Soft stabilization assemblies with pretensioned cords

ABSTRACT

A soft dynamic stabilization assembly includes a core, typically in the form of a tensioned cord, at least one pair of bone anchors, a spacer surrounding the core located between the bone anchors, typically, at least one elastic bumper and at least one fixing or blocking member. The core is slidable with respect to at least one of the bone anchors and cooperating spacer.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. Nonprovisional patentapplication Ser. No. 13/506,657, filed May 7, 2012, which claims thebenefit of U.S. Provisional Patent Application Ser. No. 61/518,421,filed May 5, 2011, both of which are fully incorporated by referenceherein for all purposes.

U.S. patent application Ser. No. 13/506,657 is also acontinuation-in-part of U.S. patent application Ser. No. 13/385,212,filed Feb. 8, 2012, which claims the benefit of U.S. Provisional PatentApplication Ser. No. 61/463,037, filed Feb. 11, 2011, both of which areincorporated by reference herein. U.S. patent application Ser. No.13/506,657 is also a continuation-in-part of U.S. patent applicationSer. No. 13/136,331, filed Jul. 28, 2011, which claims the benefit ofU.S. Provisional Patent Application Ser. No. 61/400,504, filed Jul. 29,2010, and 61/403,915, filed Sep. 23, 2010, all of which are incorporatedby reference herein. U.S. patent application Ser. No. 13/506,657 is alsoa continuation-in-part of U.S. patent application Ser. No. 12/802,849,filed Jun. 15, 2010, which claims the benefit of the following U.S.Provisional Patent Application Ser. No. 61/268,708, filed Jun. 15, 2009;61/270,754, filed Jul. 13, 2009; 61/336,911, filed Jan. 28, 2010;61/395,564, filed May 14, 2010; 61/395,752, filed May 17, 2010; and61/396,390, filed May 26, 2010; all of which are incorporated byreference herein. U.S. patent application Ser. No. 13/506,657 is also acontinuation-in-part of U.S. patent application Ser. No. 12/148,465,filed Apr. 18, 2008, which claims the benefit of U.S. Provisional PatentApplication Ser. No. 60/927,111, filed May 1, 2007, both of which areincorporated by reference herein. U.S. patent application Ser. No.13/506,657 is also a continuation-in-part of U.S. patent applicationSer. No. 12/584,980, filed Sep. 15, 2009, which claims the benefit ofU.S. Provisional Patent Application Ser. No. 61/192,312, filed Sep. 17,2008 and U.S. Provisional Patent Application Ser. No. 61/210,058, filedMar. 13, 2009, all of which are incorporated by reference herein. U.S.patent application Ser. No. 13/506,657 is also a continuation-in-part ofU.S. patent application Ser. No. 12/661,042, filed Mar. 10, 2010, whichclaims the benefit of U.S. Provisional Patent Application Ser. No.61/210,058, filed Mar. 13, 2009, all of which are fully incorporated byreference herein for all purposes.

BACKGROUND OF THE INVENTION

The present invention is directed to soft or dynamic fixation assembliesfor use in bone surgery, particularly spinal surgery, and in particularto longitudinal connecting members for such assemblies, the connectingmembers being attached to at least two bone fasteners.

Historically, it has been common to fuse adjacent vertebrae that areplaced in fixed relation by the installation therealong of bone screwsor other bone anchors and cooperating longitudinal connecting members orother elongate members. Fusion results in the permanent immobilizationof one or more of the intervertebral joints. Because the anchoring ofbone screws, hooks and other types of anchors directly to a vertebra canresult in significant forces being placed on the vertebra, and suchforces may ultimately result in the loosening of the bone screw or otheranchor from the vertebra, fusion allows for the growth and developmentof a bone counterpart to the longitudinal connecting member that canmaintain the spine in the desired position even if the implantsultimately fail or are removed. Because fusion has been a desiredcomponent of spinal stabilization procedures, longitudinal connectingmembers have been designed that are of a material, size and shape tolargely resist flexure, extension, torsion, distraction and compression,and thus substantially immobilize the portion of the spine that is to befused. Thus, longitudinal connecting members are typically uniform alongan entire length thereof, and usually made from a single or integralpiece of material having a uniform diameter or width of a size toprovide substantially rigid support in all planes.

An alternative to fusion, which immobilizes at least a portion of thespine, and the use of more rigid longitudinal connecting members orother rigid structure has been a “soft” or “dynamic” stabilizationapproach in which a flexible loop-, S-, C- or U-shaped member or acoil-like and/or a spring-like member is utilized as an elasticlongitudinal connecting member fixed between a pair of pedicle screws inan attempt to create, as much as possible, a normal loading patternbetween the vertebrae in flexion, extension, distraction, compression,side bending and torsion. Another type of soft or dynamic system knownin the art includes bone anchors connected by flexible cords or strands,typically made from a plastic material. Such a cord or strand may bethreaded through cannulated spacers that are disposed between adjacentbone anchors when such a cord or strand is implanted, tensioned andattached to the bone anchors. The spacers typically span the distancebetween bone anchors, providing limits on the bending movement of thecord or strand and thus strengthening and supporting the overall system.Such cord or strand-type systems have typically required specializedbone anchors and tooling for tensioning and holding the cord or strandin the bone anchors.

The complex dynamic conditions associated with spinal movement createchallenges for the design of elongate elastic longitudinal connectingmembers that exhibit an adequate fatigue strength to providestabilization and protected motion of the spine, without fusion, andthat allow for some natural movement of the portion of the spine beingreinforced and supported by the elongate elastic or flexible connectingmember. A further challenge are situations in which a portion or lengthof the spine requires a more rigid stabilization, possibly includingfusion, while another portion or length may be better supported by amore dynamic system that allows for protective movement.

SUMMARY OF THE INVENTION

Longitudinal connecting member assemblies according to the invention foruse between at least two bone anchors provide soft or dynamic, protectedmotion of the spine and may be extended to provide additional soft ordynamic sections or more rigid support along an adjacent length of thespine, with fusion, if desired. A longitudinal connecting memberassembly according to the invention has an inner segment or coretypically made from a cord or cords, the core being fixed at either endto substantially rigid segments or structures, including but not limitedto rods, tubes, sleeves, blocking structures or stops. The core istypically surrounded by a spacer that is usually elastomeric but may behard and rigid. Furthermore elastomeric bumpers may be used at locationsalong the connector to provide a continuous axial load. The longitudinalconnecting member assembly is typically dynamically loaded prior tobeing operatively attached to at least a pair of bone anchors along apatient's spine. The tensioned inner core or cord and one or morecompressed spacers or bumpers cooperate dynamically, such features alsohaving some flexibility in bending, with the outer spacer protecting andlimiting flexing movement of the inner core. The spacer may include oneor more grooves or other features to aid in compression uponinstallation between the rigid elongate segments.

The illustrated inner core cords of the invention are slidable withrespect to illustrated sleeves that are attached to the bone anchor.However, such cords may also may be utilized in sleeveless embodimentswherein the cord is slidable with respect to one or more bone anchorwith the cord being fixed to blockers located outside of such an anchor.Thus, also, a dynamic stabilization assembly according to the inventionfor attachment to at least two bone anchors includes an elongate innercore, preferably a tensioned cord, with at least one spacer, typicallyin the form of an elastic spacer, surrounding the core, the core andspacer disposed between the at least two bone anchors. One or moreelastic bumpers and one or more fixing structures or blockers aredisposed on opposite sides of one of the bone anchors, (and/or betweencertain bone anchors) the bumper or bumpers in compression bycooperation between one or more of the bone anchors and the blocker.

In a method of one aspect of the invention, a cord and surroundingspacer are inserted between first and second implanted bone anchors witha spacer being in contact with both of the bone anchors. The cord isfixed to the first bone anchor or to a blocker located outside the boneanchor. A bumper and a fixing structure or blocker are threaded alongthe cord until the bumper abuts the second bone anchor and the blockerabuts the bumper. The cord is tensioned and the blocker is crimped orotherwise fixed to the cord, for example, using a set screw, resultingin a tensioned cord with both the bumper and the spacer being incompression. The cord remains in sliding engagement with the second boneanchor, or with both the first and second bone anchors when there aretwo blockers, advantageously allowing for some elastic distraction ofthe system with elongation between the screw heads once implanted, aswell as compression and bending in response to spinal flexion andextension. In some embodiments according the invention, there is nooverlap between bumpers and blockers while in others, there is someoverlap. In some embodiments, blockers may be utilized without bumpers.Soft stabilization assemblies according to the invention may be utilizedwith both open and closed monoaxial bone screws as well as polyaxialbone screws. In some embodiments, the core cord member may be replacedby relatively hard stiff rods or bars or relatively soft, deformable ornon elastic rods or bars, or other longitudinal connecting members ofdifferent shapes and materials, including PEEK and other polymers andmetal cables. Assemblies of the invention may include mono- andpolyaxial open and closed screws that may be used with a first lockingfastener or closure top that fixes against the core member (cord, cable,rod or bar), or alternatively with a second locking limited travelclosure top that is fixed to the bone screw and captures the core (cord,cable, rod or bar) in the screw, but allows such core member to be insliding engagement with the bone screw. In the case of a polyaxialscrew, the polyaxial mechanism is configured to be locked by this secondclosure top while allowing the core to travel through the screw head.Such polyaxial screws may include inserts that cooperate directly withclosure tops to press down upon the bone screw shank and lock thepolyaxial mechanism without pressing on the inner core member. Open bonescrews with no set screw may also be utilized.

A variety of embodiments according to the invention are possible. Rodsor other substantially rigid structures having different measures ofrigidity may be connected according to embodiments of the invention.Either rigid lengths or flexible cords may be of greater or lesserlengths for attaching to one or a plurality of bone anchors.

It is an object of the invention to provide a lightweight, reducedvolume, low profile assembly including at least two bone anchors and asoft (or soft and hard combination) longitudinal connecting membertherebetween. Furthermore, it is an object of the invention to provideapparatus and methods that are easy to use and especially adapted forthe intended use thereof and wherein the apparatus are comparativelyinexpensive to make and suitable for use.

Other objects and advantages of this invention will become apparent fromthe following description taken in conjunction with the accompanyingdrawings wherein are set forth, by way of illustration and example,certain embodiments of this invention.

The drawings constitute a part of this specification and includeexemplary embodiments of the present invention and illustrate variousobjects and features thereof.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a dynamic fixation longitudinalconnecting member according to the invention including first and secondrigid rod portions, an inner core, an outer spacer and a pair of supportrings, and shown attached to a pair of polyaxial bone screws.

FIG. 2 is an enlarged exploded perspective view of the rigid rodportions of the connecting member of FIG. 1 .

FIG. 3 is an enlarged exploded front elevational view of the connectingmember of FIG. 1 .

FIG. 4 is an enlarged perspective view of the spacer of FIG. 1 .

FIG. 5 is an enlarged side elevational view of the spacer of FIG. 1 .

FIG. 6 is an enlarged perspective view of the spacer of FIG. 1 withportions removed to show the detail thereof.

FIG. 7 is an enlarged perspective view of one of the support rings ofFIG. 1 .

FIG. 8 is an enlarged and partial front elevational view of theconnecting member of FIG. 1 with portions broken away to show the detailthereof.

FIG. 9 is a perspective view of a second embodiment of a dynamicfixation longitudinal connecting member according to the invention shownwith three bone screws.

FIG. 10 is an enlarged perspective view of a rigid rod portion of theconnecting member of FIG. 9 .

FIG. 11 is an enlarged perspective view of three rigid rod portions andconnecting inner core ties of the connecting member of FIG. 9 .

FIG. 12 is a front elevational view of a third embodiment of a dynamicfixation longitudinal connecting member according to the inventionincluding first and second rigid rod portions, an inner core, an outerspacer, an elastic bumper and a crimping ring, and shown attached to apair of polyaxial bone screws.

FIG. 13 is an enlarged perspective view of the first rigid rod portionof FIG. 12 .

FIG. 14 is an enlarged perspective view of the second rigid rod portionof FIG. 12 .

FIG. 15 is an enlarged exploded perspective view of the connectingmember of FIG. 12 , the spacer having a portion broken away to show thedetail thereof.

FIG. 16 is an enlarged exploded front elevational view of the connectingmember of FIG. 12 , the spacer having a portion broken away to show thedetail thereof.

FIG. 17 is an enlarged front elevational view of the connecting memberof FIG. 12 with portions broken away to show the detail thereof.

FIG. 18 is an enlarged side elevational view of the spacer shown in FIG.12 .

FIG. 19 is an opposed side elevational view of the spacer of FIG. 18 .

FIG. 20 is a front elevational view of a fourth embodiment of a dynamicfixation longitudinal connecting member according to the invention shownwith three bone screws.

FIG. 21 is an enlarged exploded perspective view of rigid rod portions,a bumper and a crimping ring of the connecting member of FIG. 20 .

FIG. 22 is an enlarged perspective view of one of the spacers of theconnecting member of FIG. 20 .

FIG. 23 is a front elevational view of a fifth embodiment of a dynamicfixation longitudinal connecting member according to the invention,similar to that shown in FIG. 20 , but including an additional spacer.

FIG. 24 is a front elevational view of a sixth embodiment of a dynamicfixation longitudinal connecting member according to the invention, alsosimilar to that shown in FIG. 20 , but including an additional spacerand bumper.

FIG. 25A is a front elevational view of a seventh embodiment of adynamic fixation longitudinal connecting member according to theinvention, shown in a first state or position.

FIG. 25B is another front elevational view of the seventh embodiment ofa dynamic fixation longitudinal connecting member according to theinvention, shown in a second state or position.

FIG. 26A is another front elevational view of the embodiment shown inFIGS. 25A and B, showing the embodiment in another state or position.

FIG. 26B is another front elevational view of the embodiment shown inFIGS. 25A and B and 26A, showing the embodiment in another state orposition.

FIG. 27A is a front elevational view of an eighth embodiment of adynamic fixation longitudinal connecting member according to theinvention, shown in a first state or position.

FIG. 27B is a front elevational view of the eighth embodiment of adynamic fixation longitudinal connecting member according to theinvention, shown in a second state or position.

FIG. 28 is a partial perspective view of another soft dynamicstabilization connector of the invention having an inner cord, an outerspacer, an elastic bumper and a fixing structure or blocker, shown as acrimping structure, the connector shown with a pair of open monoaxialbone screws, one with a cord travel or sliding closure top and one witha cord compressing and locking closure top.

FIG. 29 is a partial and reduced and exploded front elevational view ofthe connector and bone screws of FIG. 28 , shown without the closuretops.

FIG. 30 is a partial front elevational view, similar to FIG. 29 showinga stage of assembly of the connector and bone screws of FIG. 28 ,showing use of a driving tool for fixing one of the first closure topsagainst the cord.

FIG. 31 is a partial top plan view with portions broken away to show thedetail thereof, showing use of a crimping tool in a further stage ofassembly of the connector and bone screws of FIG. 28 .

FIG. 32 is an enlarged and partial cross-sectional view taken along theline 32-32 of FIG. 28 .

FIG. 33 is an exploded perspective view of an alternative bone screw foruse with the invention of FIG. 28 , shown with a cord and a cord slidinglimited travel closure top.

FIG. 34 is a partial perspective view of an alternative bar for use withthe bone screw and closure top of FIG. 33 .

FIG. 35 is an enlarged and partial cross-sectional view of the bonescrew of FIG. 33 taken along the line 35-35 of FIG. 33 and showing aportion of the cord in phantom.

FIG. 36 is an enlarged and partial cross-sectional view taken along theline 36-36 of FIG. 35 and also showing the mated closure top in crosssection, a portion of the cord in phantom and an alternative closure toppossibility, such top having an upper cap or stop shown in phantom.

FIG. 37 is an exploded perspective view of the bone screw of FIG. 33shown with a second locking closure top and a deformable rod.

FIG. 38 is a partial cross-sectional view taken along the line 38-38 ofFIG. 37 and showing the second locking closure top in an early stage ofassembly.

FIG. 39 is a partial cross-sectional view, similar to FIG. 38 , showingthe second closure top fully assembled within the bone screw and engagedwith and compressing a deformable rod.

FIG. 40 is an enlarged and partial cross-sectional view of the bonescrew of FIG. 37 taken along the line 38-38, with a portion of thedeformable rod being shown in phantom.

FIG. 41 is an enlarged and partial cross-sectional view, taken along theline 41-41 of FIG. 40 , also showing the mated closure top and a portionof the deformable rod in cross-section.

FIG. 42 is a perspective view of another alternative embodiment of asoft dynamic stabilization connector of the invention having an innerrod, an elastic bumper and a blocking structure, the connector shownwith a pair of open polyaxial bone screws.

FIG. 43 is an enlarged and partial side elevational view of one of thebone screws of the embodiment of FIG. 42 with portions broken away toshow the detail thereof and also showing an alternative cap portion inphantom.

FIG. 44 is a front elevational view of another soft dynamicstabilization connector of the invention having an inner cord, anelastic bumper and a blocking structure, two spacers and shown withthree open monoaxial screws and cooperating closure tops.

FIG. 45 is another front elevational view of the connector of FIG. 44with portions broken away to show the detail thereof.

FIG. 46 is another front elevational view of the connector of FIG. 44shown in a compressed state.

FIG. 47 is a front elevational view of the connector of FIG. 46 withportions broken away to show the detail thereof.

FIG. 48 is another front elevational view of the connector of FIG. 44shown in a distracted state.

FIG. 49 is a front elevational view of the connector of FIG. 48 withportions broken away to show the detail thereof.

FIG. 50 is a front elevational view with portions broken away to showthe detail thereof of a replacement assembly wherein the soft cord,blocker, bumper and spacers of the connector of FIG. 44 have beenremoved and replaced with a hard rod.

FIG. 51 is a front elevational view of another soft dynamicstabilization connector of the invention having an inner cord, anelastic bumper and a blocking structure, a spacer, a rod/cord connector,a rod and shown with four open monoaxial screws and cooperating closuretops.

FIG. 52 is another front elevational view of the connector of FIG. 51with portions broken away to show the detail thereof.

FIG. 53 is a front elevational view of another soft dynamicstabilization connector of the invention having an inner cord, anelastic bumper and a blocking structure, two lordotic spacers, and shownwith three open monoaxial screws and cooperating closure tops.

FIG. 54 is another front elevational view of the connector of FIG. 53with portions broken away to show the detail thereof.

FIG. 55 is an enlarged, exploded and perspective view of the blocker andcooperating set screw shown in FIG. 44 .

FIG. 56 is a top plan view of the blocker of FIG. 55 .

FIG. 57 is a bottom plan view of the blocker of FIG. 55 .

FIG. 58 is a cross-sectional view taken along the line 58-58 of FIG. 56.

FIG. 59 is an enlarged perspective view of one of the spacers shown inFIG. 44 .

FIG. 60 is a reduced, exploded, perspective view of one of the open bonescrews shown in FIG. 44 , shown with both a slip and a grip closure top.

FIG. 61 is an enlarged, exploded perspective view of the rod/cordconnector and cooperating set screws shown in FIG. 51 .

FIG. 62A is a partial and enlarged front elevational view of anothersoft dynamic stabilization connector of the invention having an innercord, an elastic bumper and a blocking structure, two spacers and shown,with three closed monoaxial screws, one with a cooperating set screw,the figure shows the connector in a distracted state.

FIG. 62B is a partial and enlarged front elevational view, similar toFIG. 62A, showing the connector of FIG. 62A in a compressed state.

FIG. 62C is a partial and enlarged front elevational view, similar toFIG. 62A, showing the connector of FIG. 62A in a nominal state.

FIG. 63A is a partial front elevational view with portions broken awayof the connector of FIG. 62A.

FIG. 63B is a partial front elevational view with portions broken awayof the connector of FIG. 62B.

FIG. 63C is a partial front elevational view with portions broken awayof the connector of FIG. 62C.

FIG. 64 is a front elevational view of another soft dynamicstabilization connector of the invention having an inner cord, twoelastic bumpers, two blocking structures, two spacers and shown withthree closed monoaxial screws with no set screws.

FIG. 65 is a partial front elevational view with portions broken away ofthe connector of FIG. 64 .

FIG. 66 is a partial front elevational view of another soft dynamicstabilization connector of the invention having an inner cord, oneelastic bumper, two blocking structures, one having a break-off head,two spacers and shown with three closed monoaxial screws with no setscrews.

FIG. 67 is another partial front elevational view of the connector ofFIG. 66 , showing the spacer compressed and the blocking structurebreak-off head removed.

FIG. 68 is a partial front elevational view with portions broken away ofthe connector of FIG. 67 .

FIG. 69 is a reduced, exploded, perspective view of the closed bonescrew and cooperating set screw shown in FIGS. 62A-68 .

FIG. 70 is an exploded side elevational view of the bone screw and setscrew of FIG. 69 .

FIG. 71 is an enlarged side elevational view of the bone screw of FIG.70 with portions broken away to show the detail thereof.

DETAILED DESCRIPTION OF THE INVENTION

As required, detailed embodiments of the present invention are disclosedherein; however, it is to be understood that the disclosed embodimentsare merely exemplary of the invention, which may be embodied in variousforms. Therefore, specific structural and functional details disclosedherein are not to be interpreted as limiting, but merely as a basis forthe claims and as a representative basis for teaching one skilled in theart to variously employ the present invention in virtually anyappropriately detailed structure. It is also noted that any reference tothe words top, bottom, up and down, and the like, in this applicationrefers to the alignment shown in the various drawings, as well as thenormal connotations applied to such devices, and is not intended torestrict positioning of the connecting member assemblies of theapplication and cooperating bone anchors in actual use.

With reference to FIGS. 1-8 , the reference numeral 1 generallydesignates a non-fusion dynamic stabilization longitudinal connectingmember assembly according to the present invention. The connectingmember assembly 1 is elongate and substantially cylindrical, having acentral axis A. The connecting member assembly 1 generally includesfirst and second substantially rigid members 6 and 7 with a central,dynamic connection or transition portion or segment, generally 8,disposed therebetween. A tie or a plurality of ties 10 link the rigidmembers 6 and 7 at the central segment 8. The ties 10 may be anyflexible elongate material that fastens, secures or unites the rigidmembers 6 and 7, including, but not limited to cords, threads, strings,bands, or fibers that may be single or multiple strands, includingtwisted, braided or plaited materials. The illustrated central segment 8further includes an outer sleeve or spacer 14 and a pair of supportrings 16.

Each of the illustrated rigid members 6 and 7 are substantiallycylindrical with one or more circular cross-sections along a lengththereof. However, it is foreseen that the members 6 and 7 may have otherforms, including but not limited to oval, square and rectangularcross-sections as well as other curved or polygonal shapes. It isforeseen that the member 6 and 7 may be of different materials,different shapes or different sizes, and thus one member may be morerigid or more flexible than the other member. The members 6 and 7 eachare of a length for cooperating with at least one and up to a pluralityof bone attachment members, such as bone screws or hooks. The member 6is substantially solid, rigid and cylindrical and further includes abuttress or plate 20 having a plurality of apertures in the form ofthrough bores 22. The member 7 is also substantially solid, rigid andcylindrical and includes a buttress or plate 24 similar or identical tothe plate 20. The plate 24 also has a plurality of apertures in the formof through bores 26 running therethrough that are identical or similarto the apertures 22. Each of the bores 22 and 26 extends through therespective plate 20 and 24 at an oblique angle with respect to the axisA. It is foreseen that according to the invention the bores 22 and 26may also run parallel to the axis A. It is foreseen that the cord,cords, strands or fibers could be embedded into or adhered on the endsof the members 6 and 7.

With particular reference to FIG. 2 , in the illustrated embodiment,there is shown six bores 22 a, 22 b, 22 c, 22 d, 22 e and 22 f and sixcooperating bores 26 a, 26 b, 26 c, 26 d, 26 e and 26 f, each orientedsubstantially uniformly about the axis A. With reference to both FIGS. 2and 3 , in the illustrated embodiment, the ties 10 are in the form ofsix independent closed loops, 10 a, 10 b, 10 c, 10 d, 10 e and 10 f,oriented in a criss-cross pattern, that attach or tether the rigidmembers 6 and 7 together at the respective plates 20 and 24. The loopsare installed individually, with the individual cords 10 being at leastone of knotted, adhered, bonded or melted, to form such a closed loopafter threading though two adjacent bores in each of the plates 20 and24. For example, one looped cord 10 extends through the bores 22 a and22 b, looping about the plate 20 at a location between the bores 22 aand 22 b, and also extends through the bores 26 d and 26 e, loopingabout the plate 24 at a location between the bores 26 d and 26 e. While,in similar fashion, another cord 10 loops about the plate 22 byextending through the bores 22 d and 22 e and also about the plate 24 byextending through the bores 26 a and 26 b. As illustrated in FIG. 3 ,orienting the individual loops 10 a-10 f in such a criss-cross patternprovides a resulting dynamic corded section 8 that slopes or anglesinwardly toward the axis A at or near a central location 28 thereof,providing adequate clearance and ready acceptance of the spacer 14 aswill be described in greater detail below. It is foreseen that the cords10 may be individually looped in a configuration substantially parallelto the axis A or a variety of other orientations.

The ties 10 making up the individual or closed loops may be made from avariety of materials, including polyester or other plastic fibers,strands or threads, such as polyethylene-terephthalate. Such cord andcord-like materials usually are placed under axial tension prior tofinal installation, for example, the loops 10 a-10 f that are attachedto the plates 20 and 24 may be tensioned along the axis A for a selectedtime prior to installation of the spacer 14 to allow the cords 10 tolengthen and otherwise deform during a primary creep stage. As will bedescribed in more detail below, after the cords 10 reach secondary orsteady-state creep, further tension is then placed on the cords 10 inpreparation for installation of the spacer 14 between the plates 20 and24 to ensure dynamic pre-loading of the connector 1, with the cordedloops 10 a-10 f being in tension along the axis A while at the same timethe spacer 14 is in compression along the axis A. It is also foreseenthat in alternative embodiments of the invention, greater or fewer thansix discrete loops or even a single tie 10 may be laced through numerousapertures in the plates 20 and 24 to connect the member 6 to the member7.

Cords 10 of the invention typically do not illustrate elasticproperties, such as any significant additional axial distraction afterthe assembly 1 is operatively assembled. However, it is foreseen that insome embodiments, the ties or cords 10 may be made of a plastic orrubber (natural or synthetic) having elastic properties, allowing forsome further distraction of the central connection portion 8 at the ties10 during operation thereof.

Returning to the longitudinal connecting member rigid members 6 and 7,each of the plates 20 and 24 include respective outer planar surfaces orfaces 30 and 34 that operatively face toward one another. Furthermore,each plate 20 and 24 has a respective opposed face 36 and 38. The bores22 a-f open at both the faces 30 and 36 and the bores 26 a-f open atboth the faces 34 and 38. As illustrated in FIGS. 3 and 8 , the cords 10that form the six discrete closed loops, contact the faces 36 and 38 andattach the plate 20 to the plate 24 with the substantially planarsurfaces 30 and 34 facing each other. Extending from the faces 36 and 38are respective elongate cylindrical portions 40 and 42 of the rigidmembers 6 and 7. The portion 40 terminates at an end 44 and the portion42 terminates at an end 46. The portions 40 and 42 are each sized andshaped to attach to at least one bone anchor as will be described ingreater detail below. The illustrated portions 40 and 42 areapproximately the same size, but it is foreseen that different sizes,lengths and shapes are possible, as well as making the portions 40 and42 from different materials and also making the plates 20 and 24 frommaterials that are different than the portions 40 and 42. In theillustrated embodiment, the plates 20 and 24 are integral withrespective elongate portions 40 and 42 with the members 6 and 7 beingmade from metal, metal alloys or other suitable materials, includingplastic polymers such as polyetheretherketone (PEEK),ultra-high-molecular weight-polyethylene (UHMWP), polyurethanes andcomposites, including composites containing carbon fiber.

With particular reference to FIGS. 3-6 and 8 , the sleeve or spacer 14advantageously cooperates with the cords 10 of the central connection ortransition portion 8, providing limitation and protection of movement ofthe cords 10. The spacer 14 also protects patient body tissue fromdamage that might otherwise occur in the vicinity of the corded centralportion 8. The spacer 14 is substantially cylindrical and made from aplastic, such as a thermoplastic elastomer made from a polyurethane orpolyurethane blend. The spacer 14 has an external substantiallycylindrical outer surface 50 and an internal surface 52 defining athrough bore. The internal surface 52 is further defined by a centrallylocated surface 53 having a circular cross section and a pair ofoutwardly extending substantially conical surfaces 56 and 57 runningfrom the surface 53 to respective substantially planar end surfaces 60and 62. When cooperating with the looped cords 10, the end surfaces 60and 62 are substantially perpendicular to the axis A and the criss-crossorientation of the looped cords 10 follow the conical inner surfaces 56and 57 of the spacer 14 with the central portion 28 of the looped cordsbeing substantially aligned with the inner surface 53. It is foreseenthat in some embodiments, the spacer may be of circular, square,rectangular or other cross-section including curved or polygonal shapes.In the illustrated embodiment, the spacer 14 further includes acompression groove 64 and a pair of grooves 66 on either side of thegroove 64 sized and shaped to receive the support rings or bands 16.Spacers according to the invention may include one, none or any desirednumber of grooves. The illustrated grooves 64 and 66 are substantiallyuniform and circular in cross-section, being formed in the externalsurface 50 and extending radially toward the internal surface 52. Thesize of the internal surface 52 allows for some axially directed slidingmovement of the spacer 14 with respect to the cords 10 of the section 8.The spacer 14 further includes a radially directed elongate slit or gapopening 68 extending therethrough between the outer surface 50 and theinner surface 52 and through the end surfaces 60 and 62. With referenceto FIG. 3 , the slit or gap 68 allows for opening the spacer 14 andplacing the spacer 14 onto the cords 10 of the section 8 with the gap orslit 68 widening or expanding to receive the cords 10 and thenelastically returning the spacer 14 to an original cylindrical shape asshown in FIG. 8 , but now positioned with the inner cylindrical surface52 in sliding, rotating engagement with the cords 10 of the section 8.Also, as shown in FIG. 8 , when the spacer 14 is initially placed on thecords 10, the spacer 14 completely surrounds the cords 10 and abutsagainst the buttress plate surfaces 30 and 34. The cords 10 andcooperating compressible spacer 14 allows for some twist or turn,providing some relief for torsional stresses. The spacer 14, howeverlimits such torsional movement as well as bending movement, providingspinal support, as well as allowing for further compression of theassembly 1 at the transition segment 8. It is noted that in addition tolimiting the bendability of the central connection portion 8 and thusproviding strength and stability to the assembly 1, the spacer 14 alsokeeps scar tissue from growing into the portion 8 through the cords 10,thus eliminating the need for a sheath-like structure to be placed,adhered or otherwise applied to the cords 10 on the central connectionportion 8. In order to reduce the production of any micro wear debris,that in turn may cause inflammation, the spacer 14 inner surfaces and/orcooperating cord 10 surfaces may be coated with an ultra thin, ultrahard, ultra slick and ultra smooth coating, such as may be obtained fromion bonding techniques and/or other gas or chemical treatments.

With reference to FIGS. 3 and 7 , the support rings or bands 16 areannular and sized and shaped to encircle the spacer 14 and be closelyreceived in the grooves 66. Support rings 16 may be made from a varietyof materials, including metals, metal alloys and plastics. A preferredmaterial is tantalum. In the illustrated embodiment, the rings 16 are ofcircular cross-section and each include a slit or gap 70. The slit orgap 70 allows for opening the ring 16 and placing the ring 16 about thespacer 14 and into one of the grooves 66 with the gap or slit 70widening or expanding to receive the spacer 14 and then elasticallyreturning the ring 16 to an original circular orientation as shown inFIG. 8 , but now positioned about the spacer 14 and within one of thegrooves 66. A spot weld, adhesive, or other attachment is then appliedto close the slit 70 and secure the ring 16 to itself and about thespacer 14. The pair of rings 16 thus uniformly surround the spacer 14about the axis A and near each end surface 60 and 62, preventing a gapor gaps from forming at the slit 68. It is foreseen that according tothe invention, the support rings or bands may be made of a tough elasticmaterial and therefore not require the slit 70. During installation, themember 6 or 7 would be received by such a band and then the band wouldbe stretched about the spacer 14 and allowed to return to its originalform in one of the grooves 66. In a preferred connector 1 of theinvention wherein the members 6 and 7 are made from PEEK and cooperatewith polyethylene cords 10 and a polyurethane spacer 14, an assembly 1that is radiolucent results. In such an embodiment, it may be desirableto make the support rings 16 from a metal or metal alloy, such astantalum, to provide x-ray orientation markers.

The dynamic connecting member assembly 1 cooperates with at least a pairof bone anchors, such as polyaxial bone screws, generally 75, andcooperating closure structures 77 shown in FIG. 1 , the assembly 1 beingcaptured and fixed in place at the rigid end portions 40 and 42 bycooperation between the bone screws 75 and the closure structures 77.The dynamic section 8, that is pre-loaded and pre-tensioned, is disposedbetween the bone screws 75.

It is noted that an advantageous connecting member 1 according to theinvention includes a portion 42 made from a metal alloy such asstainless steel that is elongate and intended for fusion along a majorportion or section of the spine, for example, the portion 42 may besized to extend from the sacrum to the thoracic spinal segment T10. Suchan elongate portion 42 is thus connectable to a plurality of boneanchors along the spine. Such a connecting member further includes adynamic section 8, having cords 10 and spacer 14 that is sized forplacement, for example, between T9 and T8. Such an embodiment isbelieved to minimize rapid degeneration and compressive fractures thattend to occur near ends of such elongate connecting member assemblies.

Because the portions 40 and 42 are substantially solid and cylindrical,the connecting member assembly 1 may be used with a wide variety of boneanchors already available for cooperation with rigid rods includingfixed, monoaxial bone screws, hinged bone screws, polyaxial bone screws,and bone hooks and the like, with or without compression inserts, thatmay in turn cooperate with a variety of closure structures havingthreads, flanges, or other structure for fixing the closure structure tothe bone anchor, and may include other features, for example, break-offtops and inner set screws. The bone anchors, closure structures and theconnecting member assembly 1 are then operably incorporated in anoverall spinal implant system for correcting degenerative conditions,deformities, injuries, or defects to the spinal column of a patient.

The illustrated polyaxial bone screws 75 each include a shank 80 forinsertion into a vertebra (not shown), the shank 80 being pivotallyattached to an open receiver or head 81. The shank 80 includes athreaded outer surface and may further include a central cannula orthrough-bore disposed along an axis of rotation of the shank to providea passage through the shank interior for a length of wire or pininserted into the vertebra prior to the insertion of the shank 80, thewire or pin providing a guide for insertion of the shank 80 into thevertebra. The receiver 81 has a pair of spaced and generally parallelarms 85 that form an open generally U-shaped channel therebetween thatis open at distal ends of the arms 85. The arms 85 each include radiallyinward or interior surfaces that have a discontinuous guide andadvancement structure mateable with cooperating structure on the closurestructure 77. The guide and advancement structure may take a variety offorms including a partial helically wound flangeform, a buttress thread,a square thread, a reverse angle thread or other thread like ornon-thread like helically wound advancement structure for operablyguiding under rotation and advancing the closure structure 77 downwardbetween the receiver arms 85 and having such a nature as to resistsplaying of the arms 85 when the closure 77 is advanced into theU-shaped channel. For example, a flange form on the illustrated closure77 and cooperating structure on the arms 85 is disclosed in Applicant'sU.S. Pat. No. 6,726,689, which is incorporated herein by reference.

The shank 80 and the receiver 81 may be attached in a variety of ways.For example, a spline capture connection as described in Applicant'sU.S. Pat. No. 6,716,214, and incorporated by reference herein, may beused for the embodiment disclosed herein. Polyaxial bone screws withother types of capture connections may also be used according to theinvention, including but not limited to, threaded connections,frictional connections utilizing frusto-conical or polyhedral capturestructures, integral top or downloadable shanks, and the like. Also, asindicated above, polyaxial and other bone screws for use with connectingmembers of the invention may have bone screw shanks that attach directlyto the connecting member portion or segment 40 or 42, or may includecompression members or inserts that cooperate with the bone screw shank,receiver and closure structure to secure the connecting member assembly1 to the bone screw and/or fix the bone screw shank at a desired anglewith respect to the bone screw receiver that holds the longitudinalconnecting member assembly 1. It is foreseen that if the connectingmember portions 40 and 42 are fabricated from a plastic such aspolyetheretherketone (PEEK), it may be desirable to utilize bone screwsthat include one or both upper and lower compression inserts that have asaddle or U-shape configuration to closely engage such segments withinthe bone screw receiver. Although the closure structure 77 of thepresent invention is illustrated with the polyaxial bone screw 75 havingan open receiver or head 81, it is also foreseen that a variety ofclosure structures may be used in conjunction with any type of medicalimplant having an open or closed head, including monoaxial bone screws,hinged bone screws, hooks and the like used in spinal surgery.

To provide a biologically active interface with the bone, the threadedshank 80 may be coated, perforated, made porous or otherwise treated.The treatment may include, but is not limited to a plasma spray coatingor other type of coating of a metal or, for example, a calciumphosphate; or a roughening, perforation or indentation in the shanksurface, such as by sputtering, sand blasting or acid etching, thatallows for bony ingrowth or ongrowth. Certain metal coatings act as ascaffold for bone ingrowth. Bio-ceramic calcium phosphate coatingsinclude, but are not limited to: alpha-tri-calcium phosphate andbeta-tri-calcium phosphate (Ca₃(PO₄)₂, tetra-calcium phosphate(Ca₄P₂O₉), amorphous calcium phosphate and hydroxyapatite(Ca₁₀(PO₄)₆(OH)₂). Coating with hydroxyapatite, for example, isdesirable as hydroxyapatite is chemically similar to bone with respectto mineral content and has been identified as being bioactive and thusnot only supportive of bone ingrowth, but actively taking part in bonebonding.

With reference to FIG. 1 , the closure structure 77 can be any of avariety of different types of closure structures for use in conjunctionwith the present invention with suitable mating structure on theinterior surface of the upstanding arms 85 of the receiver 81. Theillustrated closure structure 77 is rotatable between the spaced arms85, but could be a slide-in closure structure. As described above, theillustrated closure structure 77 is substantially cylindrical andincludes an outer helically wound guide and advancement structure in theform of a flange form 88 that operably joins with the guide andadvancement structure disposed on the interior of the arms 85. Theillustrated closure structure 77 includes a lower or bottom surface thatis substantially planar and may include a point and/or a rim protrudingtherefrom for engaging the portion 40 or 42 outer cylindrical surface.The closure structure 77 has a top surface 90 with an internal drivefeature 92, that may be, for example, a star-shaped drive aperture soldunder the trademark TORX. A driving tool (not shown) sized and shapedfor engagement with the internal drive feature 92 is used for bothrotatable engagement and, if needed, disengagement of the closure 77from the arms 85. The tool engagement structure 92 may take a variety offorms and may include, but is not limited to, a hex shape or otherfeatures or apertures, such as slotted, tri-wing, spanner, two or moreapertures of various shapes, and the like. It is also foreseen that theclosure structure 77 may alternatively include a break-off head designedto allow such a head to break from a base of the closure at apreselected torque, for example, 70 to 140 inch pounds. Such a closurestructure would also include a base having an internal drive to be usedfor closure removal.

In use, at least two bone screws 75 are implanted into vertebrae for usewith the longitudinal connecting member assembly 1. Each vertebra may bepre-drilled to minimize stressing the bone. Furthermore, when acannulated bone screw shank is utilized, each vertebra will have a guidewire or pin (not shown) inserted therein that is shaped for the bonescrew cannula of the bone screw shank 80 and provides a guide for theplacement and angle of the shank 80 with respect to the cooperatingvertebra. A further tap hole may be made and the shank 80 is then driveninto the vertebra by rotation of a driving tool (not shown) that engagesa driving feature on or near a top portion of the shank 80. It isforeseen that the screws 75 and the longitudinal connecting memberassembly 1 can be inserted in a percutaneous or minimally invasivesurgical manner.

With particular reference to FIGS. 2, 3 and 8 , the longitudinalconnecting member assembly 1 is factory assembled to include the loopedties 10 that are initially tensioned to steady state and thereafterfurther tensioned to receive the spacer 14 that is cut to a desired sizeso that the spacer 14 is axially compressed between the plates 20 and 24after insertion of the spacer 14 about the cords or ties 10 and betweensuch plates 20 and 24. In such process, the spacer 14 is opened orexpanded at the slit 68 and moved into position over the cords 10 of thecentral portion 8 and between the plates 20 and 24 and then allowed toelastically return to an original cylindrical form as shown in FIG. 8 .The spacer 14 is also axially compressed during insertion such that thespacer 14 easily slides and is received between the surfaces 30 and 34.Thereafter, the rings or bands 16 are expanded at the respective slits70 and moved into position in the grooves 66, followed by spot weldingthereof to result in closed rings 16 encircling the spacer 14. Theresulting connecting member assembly 1 is thus dynamically loaded withthe cords 10 in tension and the spacer 14 in compression. In someembodiments according to the invention it may be desirable to place oneor more pins through the plates 20 and 24 and into the spacer 14 toprevent rotation of the spacer 14 about the axis A relative to theplates 20 and 24. It may also be desirable to use such pins as x-raymarkers.

With further reference to FIG. 1 , the pre-loaded connecting memberassembly 1 is eventually positioned in an open or percutaneous manner incooperation with the at least two bone screws 75 with the cords 10 andthe spacer 14 disposed between and spaced from the two bone screws 75and with the portions 40 and 42 each being within a U-shaped channel ofa cooperating bone screw 75. It is noted that the portions 40 and/or 42near respective ends 44 and 46 may be selectively trimmed or cut to sizebefore or at the time of surgery, or if longer, attached to the spinewith additional bone anchors. Once a desired position is attained, aclosure structure 77 is then inserted into and advanced between the arms85 of each of the bone screws 75. The closure structure 77 is rotated,using a tool (not shown) engaged with the inner drive 92 until aselected pressure is reached at which point the section 40 or 42 isurged toward, but not completely seated in the U-shaped channel of thebone screw 75. For example, about 80 to about 120 inch pounds pressuremay be required for fixing the bone screw shank 80 with respect to thereceiver 81 at a desired angle of articulation.

The assembly 1 is thus substantially dynamically loaded and orientedrelative to the cooperating vertebra, providing relief (e.g., shockabsorption) and protected movement with respect to flexion, extension,distraction and compressive forces placed on the assembly 1 and the twoconnected bone screws 75. The looped cords 10 and the spacer 14 allowfor some twisting or turning, providing some relief for torsionalstresses. Furthermore, the compressed spacer 14 places some limits ontorsional movement as well as bending movement, to provide spinalsupport. The pre-loaded cords 10 (in tension) and spacer 14 (incompression) allow for compression and some extension of the assembly 1located between the two bone screws 75, e.g., shock absorption.

If removal of the assembly 1 from any of the bone screw assemblies 75 isnecessary, or if it is desired to release the assembly 1 at a particularlocation, disassembly is accomplished by using the driving tool (notshown) with a driving formation cooperating with the closure structure77 internal drive 92 to rotate and remove the closure structure 77 fromthe receiver 81. Disassembly is then accomplished in reverse order tothe procedure described previously herein for assembly.

Eventually, if the spine requires more rigid support, the connectingmember assembly 1 according to the invention may be removed and replacedwith another longitudinal connecting member, such as a solid rod, havingthe same diameter as the portions 40 and 42, utilizing the samereceivers 81 and the same or similar closure structures 77.Alternatively, if less support is eventually required, a less rigid,more flexible assembly, for example, an assembly 1 having portions 40and 42 made of a more flexible material, but with the same diameter asthe rigid portions 40 and 42, may replace the assembly 1, also utilizingthe same bone screws 75.

With reference to FIGS. 9-11 , an alternative longitudinal connectingmember assembly according to the invention, generally 101, has a centralaxis B and includes rigid members 105, 106 and 107 and first and seconddynamic connection portions or sections 108 and 108A. The dynamicsections 108 and 108A include respective closed looped cords 110 and110A, respective spacers 114 and 114A and respective support rings 116and 116A. The connecting member assembly 101 provides for two dynamicsupport sections between a plurality of vertebrae. The illustratedembodiment is shown attached to three bone screws 75 and cooperatingclosure structures 77 previously described herein. The illustrated rigidmembers 105, 106 and 107 are each sized for attachment to a single boneanchor or screw. However, it is noted that each such rigid member 105,106 and 107 may be of greater length (along the axis B) for operativeattachment to two or more bone anchors. Furthermore, more than one rigidmember 105 may be disposed between rigid members 106 and 107 to providea plurality of dynamic sections.

The illustrated members 106 and 107 are identical or substantiallysimilar to respective members 6 and 7 previously described herein withrespect to the connecting member 1, the member 106 having an end plate120 and a plurality of bores 122 similar to the plate 20 and bores 22previously described herein and the member 107 having an end plate 124and a plurality of bores 126 similar to the plate 24 and bores 26previously described herein with respect to the member 7. Also, theclosed looped cords 110 and 110A are identical or substantially similarto the closed looped cords 10 previously described herein with respectto the connecting member 1 with the cooperating spacers 114 and 114Abeing identical or substantially similar to the spacer 14 previouslydescribed herein with respect to the connecting member 1. Also, thesupport rings 116 and 116A are identical or substantially similar to thesupport rings 16 previously described herein with respect to theconnecting member 1. However, in the connecting member 101, rather thanhaving closed looped cords that directly attach the members 106 and 107as previously described with respect to the members 6 and 7, the closedlooped cords 110 attach the member 105 with the member 106 and theclosed looped cords 110A attach the member 105 with the member 107 in amanner substantially identical to what has been described herein withrespect to the close looped cords 10 of the connecting member 1.

Thus, the member 105 may also be considered to be an extender memberthat is disposed between the members 106 and 107 and is attached to eachof such members with the respective closed looped cords 110 and 110A toprovide an additional dynamic segment to the assembly 101. Theillustrated member 105 includes a pair of opposed end plates 182 and 183and an integral cylindrical mid-portion 184 extending therebetween. Theend plates 182 and 183 are identical or substantially similar to theplates 20 and 24 previously described herein with respect to the members6 and 7. Thus, the end plates 182 and 183 include respective aperturesor through bores 186 and 187 for receiving the respective closed loopedcords 110 and 110A. In the illustrated embodiment there are six bores186 cooperating with the six bores 122 of the member 6 and six bores 187for cooperating with the six bores 126 of the member 107. The loopedcords 110 loop through the bores 122 and the bores 186 while the loopedcords 110A loop through the bores 126 and the bores 187. The illustratedcylindrical mid-portion 184 is sized to be received between arms 85 ofat least one bone screw 75.

In use, the closed looped cords 110 and 110A are installed in the samemanner as previously described herein with respect to the closed loopedcords 10 and the spacers 114 and 114A and cooperating support rings 116and 116A are installed in the same manner as previously described hereinwith respect to the spacer 14 and the rings 16. Thereafter, thepre-tensioned, pre-compressed connecting member 101 is positioned in anopen or percutaneous manner in cooperation with the at least three bonescrews 75 with the cords 110 and 110A and cooperating spacers 114 and114A each disposed between and spaced from such bone screws 75 andportions of the members 105, 106 and 107 each being within a U-shapedchannel of a cooperating bone screw 75. A closure structure 77 is theninserted into and advanced between the arms 85 of each of the bonescrews 75 to capture and lock the connecting member 101 in a desiredlocation and position along the spine. Disassembly, removal andreplacement of the connecting member assembly 101 with a more or lessrigid connecting member may be performed in a manner as previouslydescribed herein with respect to the connecting member assembly 1.

With reference to FIGS. 12-19 , another alternative longitudinalconnecting member assembly according to the invention, generally 201 iselongate and substantially cylindrical, having a central axis C. Theconnecting member assembly 201 generally includes a first rigid anchormember 206 and a second rigid terminal member 207. A central, dynamicconnection or transition portion or segment, generally 208, is disposedbetween the members 206 and 207. A tie, cord or a plurality of ties orcords 210 loop about and through apertures of the anchor member 206 andextend through a bore in the terminal member 207. The ties 210 may beany flexible elongate material that fastens, secures or unites the rigidmembers 206 and 207, including, but not limited to cords, threads,strings, bands, or fibers that may be single or multiple strands,including twisted, braided or plaited materials. The illustrated centralsegment 208 further includes a closed, non-slitted outer sleeve orspacer 214. The assembly 201 further includes an elastic bumper 217 anda crimping ring 219.

Each of the illustrated rigid members 206 and 207 are substantiallycylindrical with one or more circular cross-sections along a lengththereof. However, it is foreseen that the members 206 and 207 may haveother forms, including but not limited to oval, square and rectangularcross-sections as well as other curved or polygonal shapes. It isforeseen that the members 206 and 207 may be of different materials,different shapes or different sizes, and thus one member may be morerigid or more flexible than the other member. The members 206 and 207each are of a length for cooperating with at least one and up to aplurality of bone attachment members, such as bone screws or hooks.

With particular reference to FIGS. 12, 13 and 17 , the anchor member 206is substantially solid, rigid and cylindrical and further includes abuttress or plate 220 having a plurality of apertures in the form ofthrough bores 222. The member 206 is identical or substantially similarto the member 6 previously described herein with respect to theconnecting member assembly 1. The illustrated anchor member 206 has sixbores 222 that extend through the plate 220 at an oblique angle withrespect to the axis C as best shown in FIG. 17 . It is foreseen thataccording to the invention the bores 222 may also run parallel to theaxis C. The ties or cords 210 are in the form of six independent openloops installed individually by looping through pairs of adjacent bores222 and then extending outwardly away from the plate 220 as shown inFIGS. 15 and 16 . Similar to the cords 10 discussed previously herein,the cords 210 are placed under axial tension along the axis C for aselected time prior to final, fixed installation with the othercomponents 214, 207, 217 and 219 to lengthen and otherwise deform thecords 210 during a primary creep stage. After the cords 210 reachsecondary or steady-state creep, further tension is then placed on thecords 210 in preparation for final tightening and crimping of the ring219 as will be described in greater detail below. It is also foreseenthat in alternative embodiments of the invention, greater or fewer thansix discrete open loops may be laced through apertures in the plate 220and pulled through the member 207.

The cords 210 of the invention typically do not illustrate elasticproperties, such as any significant additional axial distraction afterthe assembly 201 is operatively assembled. However, it is foreseen thatin some embodiments, the ties or cords 210 may be made of a plastic orrubber (natural or synthetic) having elastic properties, allowing forsome further distraction of the central connection portion 208 at theties 210 during operation thereof.

With particular reference to FIG. 14 , the terminal member 207 includesa buttress or plate 224 and in inner surface 226 that forms a throughbore extending through the entire member 207 in an axial direction,sized and shaped for receiving a length of the bundled cords 210. Whenoperatively connected to the member 206, the bore formed by the innersurface 226 extends along the axis C. With further reference to FIGS.15-17 , each of the plates 220 and 224 include respective outer planarsurfaces or faces 230 and 234 that operatively face toward one another.Furthermore, each plate 220 and 224 has a respective opposed face 236and 238. The bores 222 open at both the faces 230 and 236. The innersurface 226 forming the bore of the member 207 opens at the outer planarsurface 234 and also at an end 239. The cords 210 that form the discreteopen loops, loop about and contact the face 236, extend along the axis Cwithin the inner surface 226 and extend through the end 239. Extendingfrom and integral to the faces 236 and 238 are respective elongatecylindrical portions 240 and 242 of the respective anchor member 206 andthe terminal member 207. The portion 240 terminates at an end 244. Theopen cords 210 extend completely through the elongate cylindricalportion 242 and into the bumper 217 and the crimping ring 219.

The portions 240 and 242 are each sized and shaped to attach to at leastone bone anchor as will be described in greater detail below. Theillustrated portions 240 and 242 are approximately the same size andlength, but it is foreseen that different sizes, lengths and shapes arepossible, as well as making the portions 240 and 242 from differentmaterials and also making the plates 220 and 224 from materials that aredifferent than the portions 240 and 242. In the illustrated embodiment,the plates 220 and 224 are integral with respective elongate portions240 and 242 with the members 206 and 207 being made from metal, metalalloys or other suitable materials, including plastic polymers such aspolyetheretherketone (PEEK), ultra-high-molecular weight-polyethylene(UHMWP), polyurethanes and composites, including composites containingcarbon fiber.

With particular reference to FIGS. 15-19 , the sleeve or spacer 214advantageously cooperates with the cords 210 of the central connectionor transition portion 208, providing limitation and protection ofmovement of the cords 210. The spacer 214 also protects patient bodytissue from damage that might otherwise occur in the vicinity of thecorded central portion 208. The spacer 214 is substantially cylindricaland made from a plastic, such as a thermoplastic elastomer made from apolyurethane or polyurethane blend. The spacer 214 has an externalsubstantially cylindrical outer surface 250 and an internal surface 252defining a through bore. The internal surface 252 is further defined bya substantially cylindrical surface 253 having a circular cross sectionand an outwardly extending substantially conical surface 256 runningfrom the surface 253 to a substantially planar end surface 260. Thespacer 214 further includes an opposed planar end surface 262. The innercylindrical surface 253 opens to the end surface 262.

When operatively cooperating with the looped cords 210, the end surfaces260 and 262 of the spacer 214 are substantially perpendicular to theaxis C. Also, when installed within the inner cylindrical surface 226,the cords 210 are drawn inwardly from the bores 222 and toward the axisC. The conical inner surface 256 of the spacer 214 provides clearancefor the cords 210 at the plate surface 230 while the cylindrical innersurface 253 aligns the cords 210 with the inner bore formed by the innersurface 226 of the terminal member 207. It is also foreseen that thecords 210 may be twisted or otherwise connected to form a substantiallycylindrical unit prior to insertion in the spacer 214 and the terminalmember 207. It is foreseen that in some embodiments, the spacer 214 maybe of circular, square, rectangular or other cross-section includingcurved or polygonal shapes. In the illustrated embodiment, the spacer214 further includes a compression groove 264. Spacers according to theinvention may include one, none or any desired number of grooves. Theillustrated groove 264 is substantially uniform and circular incross-section, being formed in the external surface 250 and extendingradially toward the internal surface 252. The size of the internalsurface 252 allows for some axially directed sliding movement of thespacer 214 with respect to the cords 210. The cords 210 and cooperatingcompressible spacer 214 allow for some twist or turn, providing somerelief for torsional stresses. The spacer 214, however limits suchtorsional movement as well as bending movement, providing spinalsupport, as well as allowing for further compression of the assembly 1at the flexible central connection portion 208. It is noted that inaddition to limiting the bendability of the central connection portion208 and thus providing strength and stability to the assembly 201, thespacer 214 also keeps scar tissue from growing into the portion 208through the cords 210, thus eliminating the need for a sheath-likestructure to be placed, adhered or otherwise applied to the cords 210 onthe central connection portion 208. In order to reduce the production ofmicro wear debris, that in turn may cause inflammation, the spacer 214inner surfaces and/or cooperating cord 210 surfaces may be coated withan ultra thin, ultra hard, ultra slick and ultra smooth coating, such asmay be obtained from ion bonding techniques and/or other gas or chemicaltreatments.

With particular reference to FIGS. 15 to 17 , the bumper 217 issubstantially cylindrical, including an outer surface 270 and an innersurface 272 forming a substantially cylindrical through bore that opensat planar end surfaces 274 and 276 and operatively extends along theaxis C. The bumper 217 further includes a compression groove 278 that issimilar in form and function to the compression groove 264 of the spacer214. The bumper 217 is sized and shaped to receive the elongate cords210 through the inner surface 272. The bumper 217 is preferably madefrom an elastomeric material such as polyurethane. The bumper 217provides axial elastic distraction of the cords 210 as will be describedin greater detail below.

Also with reference to FIGS. 15 to 17 , the crimping ring 219 issubstantially cylindrical and includes an outer surface 280 and an innersurface 282 forming a substantially cylindrical through bore that opensat planar end surfaces 284 and 286 and operatively extends along theaxis C. The crimping ring 219 is sized and shaped to receive theelongate cords 210 through the inner surface 282. The crimping ring 219further includes a pair of crimp or compression grooves 288 that arepressable and deformable inwardly toward the axis C upon finaltensioning of the cords 210 during assembly of the connector 201 toengage and hold the cords 210 in tension and thereby transmitcompressive force to the elastic spacer 214. The crimping ring 219 ispreferably made from a stiff, but deformable material, including metalsand metal alloys. As will be discussed with respect to a furtherembodiment of the invention described below, the cords 210 may bethreaded through two crimping rings 219 placed adjacent to one another,with a preliminary crimping ring being at a terminal end of the assembly201. Such a preliminary ring is crimped to initially lock the assemblytogether with the cords 210 in tension. If further creep and deformationof the cords 210 decreases the axial tension on the cords 210 within theassembly 201, the cords 210 may be re-tensioned and locked into placewith the second or final crimping ring. The preliminary crimping ringmay then be sliced off of the assembly 201 and discarded.

With reference to FIG. 12 , the dynamic connecting member assembly 201cooperates with at least a pair of bone anchors, such as the polyaxialbone screws, generally 75, and cooperating closure structures 77described previously herein, the assembly 201 being captured and fixedin place at the rigid portions 240 and 242 by cooperation between thebone screws 75 and the closure structures 77. The dynamic section 208,that is pre-loaded and pre-tensioned, is disposed between the bonescrews 75.

With particular reference to FIGS. 12 and 15-17 , the longitudinalconnecting member assembly 201 is factory assembled by looping six ties210 about and through the bores 222 of the plate 220 of the anchormember 207 to form the twelve strands or cords 210 that are thenthreaded through the remaining components of the assembly 201. It isnoted that the ties 210 may be initially tensioned to steady state andthereafter further tensioned after assembly with the other components.Alternatively, the twelve cords or strands 210 that are anchored to themember 206 are initially passed through the spacer 214 inner surface252, followed by the terminal member 207 internal surface 226, then thebumper 217 inner surface 272 and finally the crimping ring 219 innersurface 282 and out the end 286. Thereafter, the spacer 214, theterminal member 207, the bumper 217 and the crimping ring 219 aresnugged up against the plate 220 of the anchor member 206 and tension isapplied to the bundle of twelve cords 210. Tension is increased on thecord bundle 210 until the elastic spacer 214 and the elastic bumper 217are compressed and the cords 210 have stopped stretching. Thereafter,the crimping ring 219 is crimped using a tool (not shown) that presseson the opposed grooves 288 and deforms toward the axis C to make contactand firmly grip the cords 210, keeping the cords 210 in the desiredtension and locking the components of the assembly 201 in place. Theresulting connecting member assembly 201 is thus dynamically loaded withthe cords 210 in tension and the spacer 214 and elastic bumper 217 incompression. In some embodiments according to the invention it may bedesirable to place one or more pins through the plates 220 and 224 andinto the spacer 214 to prevent rotation of the spacer 214 about the axisC relative to the plates 220 and 224. It may also be desirable to usesuch pins as x-ray markers.

With further reference to FIG. 12 , the pre-loaded connecting memberassembly 201 is eventually positioned in an open or percutaneous mannerin cooperation with the at least two bone screws 75 with the spacer 214disposed between and spaced from the two bone screws 75 and with theportions 240 and 242 each being within a U-shaped channel of acooperating bone screw 75. A closure structure 77 is then inserted intoand advanced between the arms 85 of each of the bone screws 75. Theclosure structure 77 is rotated, using a tool (not shown) engaged withthe inner drive 92 until a selected pressure is reached at which pointthe section 240 or 242 is urged toward, but not completely seated in theU-shaped channel of the bone screw 75. For example, about 80 to about120 inch pounds pressure may be required for fixing the bone screw shank80 with respect to the receiver 81 at a desired angle of articulation.

The assembly 201 is thus substantially dynamically loaded and orientedrelative to the cooperating vertebra, providing relief (e.g., shockabsorption) and protected movement with respect to flexion, extension,distraction and compressive forces placed on the assembly 201 and thetwo connected bone screws 75. The looped cords 210 and the spacer 214allow for some twisting or turning, providing some relief for torsionalstresses. Furthermore, the compressed spacer 214 places some limits ontorsional movement as well as bending movement, to provide spinalsupport. The pre-loaded cords 210 (in tension) and spacer 214 (incompression) allow for compression and some extension of the assembly201 located between the two bone screws 75, e.g., shock absorption.Disassembly, removal and replacement of the connecting member assembly201 with a more or less rigid connecting member may be performed in amanner as previously described herein with respect to the connectingmember assembly 1.

With reference to FIGS. 20-22 , another longitudinal connecting memberassembly according to the invention, generally 301, has a central axis Dand includes an intermediate rigid member 305, a rigid anchor member306, a rigid terminal member 307 and first and second dynamic connectionportions or sections 308 and 308A. An open loop cord bundle 310 extendsthrough both the sections 308 and 308A. The dynamic sections 308 and308A further include respective spacers 314 and 314A. The connectingmember assembly 301 provides for two dynamic support sections between aplurality of vertebrae. The illustrated embodiment is shown attached tothree bone screws 75 and cooperating closure structures 77 previouslydescribed herein. The illustrated rigid members 305, 306 and 307 areeach sized for attachment to a single bone anchor or screw. However, itis noted that each such rigid member 305, 306 and 307 may be of greaterlength (along the axis D) for operative attachment to two or more boneanchors. Furthermore, more than one rigid member 305 may be disposedbetween rigid members 306 and 307 to provide a plurality of dynamicsections.

The connecting member assembly 301 is substantially similar to theconnecting member assembly 201 previously described herein with theexception of three components: the additional intermediate rigid member305, the additional spacer 314A and the additional crimping ring 319A.The illustrated members 306 and 307 are identical or substantiallysimilar to respective members 206 and 207 previously described hereinwith respect to the connecting member 201, the member 306 having an endplate 320 and a plurality of bores 322 similar to the plate 220 andbores 222 previously described herein and the member 307 having an endplate 324 and a through bore 326 similar to the plate 224 and bore 226previously described herein with respect to the member 207. Also, theopen looped cord bundle 310 is identical or substantially similar to theopen looped cord bundle 210, with the exception that the bundle 310 isof greater axial length (along the axis D) as compared to the cordedbundle 210 previously described herein with respect to the connectingmember 201. The spacer 314 that is disposed between the member 306 andthe member 305 is identical or substantially similar to the spacer 214previously described herein with respect to the connecting member 201.Also, the elastic bumper 317 and both crimping rings 319 and 319A areidentical or substantially similar to the respective bumper 217 andcrimping ring 219 previously described herein with respect to theconnecting member 201.

With particular reference to FIGS. 20 and 21 , the intermediate rigidmember 305 is disposed between the members 306 and 307 and provides foran additional dynamic connection section 308A. In particular, the member301 includes a pair of opposed end plates 382 and 383 and an integralcylindrical mid-portion 384 that extends therebetween. The end plates382 and 383 are identical or substantially similar to the plate 324 ofthe member 307. The member 305 further includes a through bore 386running through the entire member 305, from the end plate 382 to the endplate 383 and axially centrally through the cylindrical mid-portion 384.The illustrated cylindrical mid-portion 384 is sized to be receivedbetween arms 85 of at least one bone screw 75.

The spacer 314 receives the cord bundle 310 at a location between theplate 320 of the anchor member 306 and the plate 382 of the intermediaterigid member 305. The spacer 314A receives the cord bundle 310 at alocation between the plate 383 of the member 305 and the plate 324 ofthe terminal member 307. The illustrated spacer 314A is substantiallysimilar to the spacer 314 and the spacer 214 previously described hereinwith respect to the connecting member assembly 201, having an outercylindrical surface 390, an inner surface 392 defining a through borerunning between planar surfaces 394 and 395 and at least one outercompression groove 396. However, unlike the spacers 214 and 314, theinner surface 392 of the spacer 314A is cylindrical and defines a boreof constant circular cross-section sized and shaped to receive a lengthof the cord bundle 310.

In use, the open looped cord bundle 310 is installed on the anchormember 306 by looping through the apertures 322 in the same manner aspreviously described herein with respect to the installation of the openlooped cord bundle 210 through the apertures 222. The twelve cords orstrands 310 that are anchored to the member 306 are initially passedthrough the bore in the spacer 314, followed by the bore formed by theintermediate member 305 internal cylindrical surface 386, then the boreformed by the spacer 314A internal surface 392, followed by the boreformed by the terminal member 307 internal surface 326, then the bore ofthe bumper 317, the bore of the crimping ring 319 and finally throughthe bore of the crimping ring 319A. Thereafter, the spacer 314, theintermediate member 305, the spacer 314A, the terminal member 307, thebumper 317, the crimping ring 319 and the crimping ring 319A are snuggedup against the plate 320 of the anchor member 306 and tension is appliedto the bundle of twelve cords 310. Tension is increased on the cordbundle 310 until the elastic spacers 314 and 314A and the elastic bumper317 are compressed and the cords 310 have stopped stretching.Thereafter, the end crimping ring 319A is crimped using a tool (notshown) that presses on opposed grooves of the ring 319A and deforms thering toward the axis D to make contact and firmly grip the cords 310. Ifviscoelastic changes decrease the axial tension in the cord bundle 310,the assembly 301 may be re-tensioned by pulling the cords 310 away fromthe anchor member 306 until a desired tension is again reached. At thattime, the other crimping ring 319 is crimped using a tool (not shown)that presses on opposed grooves of the ring 319 and deforms the ringtoward the axis D to make contact and firmly grip the cords 310.Thereafter, the crimping ring 319A is sliced off of the assembly 301.The resulting connecting member assembly 301 is thus dynamically loadedwith the cords 310 in tension with the spacers 314 and 314A and theelastic bumper 317 in compression.

With further reference to FIG. 20 , the pre-loaded connecting memberassembly 301 is eventually positioned in an open or percutaneous mannerin cooperation with the at least three bone screws 75 with the spacers314 and 314A disposed between and spaced from the bone screws 75 andwith cylindrical portions of each of the members 305, 306 and 307 beingwithin a U-shaped channel of a cooperating bone screw 75. A closurestructure 77 is then inserted into and advanced between the arms 85 ofeach of the bone screws 75. The closure structure 77 is rotated, using atool (not shown) engaged with the inner drive 92 until a selectedpressure is reached, for example, about 80 to about 120 inch poundspressure may be required for fixing the bone screw shank 80 with respectto the receiver 81 at a desired angle of articulation.

The assembly 301 is thus substantially dynamically loaded and orientedrelative to the cooperating vertebra, providing relief (e.g., shockabsorption) and protected movement with respect to flexion, extension,distraction and compressive forces placed on the assembly 301 and thethree connected bone screws 75. The cords 310 and the spacers 314 and314A allow for some twisting or turning, providing some relief fortorsional stresses. Furthermore, the compressed spacers 314 and 314Aplace some limits on torsional movement as well as bending movement, toprovide spinal support. The pre-loaded cords 310 (in tension) andspacers 314 and 314A (in compression) allow for compression and someextension of the assembly 301 located between the two bone screws 75,e.g., shock absorption. Disassembly, removal and replacement of theconnecting member assembly 301 with a more or less rigid connectingmember may be performed in a manner as previously described herein withrespect to the connecting member assembly 1.

With reference to FIGS. 23 and 24 , dynamic or soft stabilizationassemblies are shown that are almost identical to that shown in FIG. 20with some exceptions. FIG. 23 shows the use of an additional spacer 314located outside of the bone screw 75′. FIG. 24 illustrates both anadditional spacer 314 and an additional elastomeric bumper 317 locatedoutside of the bone screw 75″.

With reference to FIGS. 25A and 25B, a soft stabilization assembly isshown that is substantially similar to that shown in FIG. 20 , with theexception that only two bone screws are shown and the member 306 isreplaced by a plate Q that fixes the cord or cord bundle 310′ at an endof the assembly while the cord is allowed to be slidable with respect tothe bone screw 75″. FIGS. 25A and B illustrate the assembly in twostates of dynamic stabilization that occur without the cord 310′changing length. In state “A” shown in FIG. 25A, both the spacers 314are compressed, while the bumper 317 is allowed to expand to a neutralstate. In state “B” shown in FIG. 25B, the bumper 317 is compressed andthe spacers 314 are in an expanded state.

FIGS. 26A and 26B illustrate the same assembly as in FIGS. 25A and 25B,also in two states of dynamic stabilization. In state “C” shown in FIG.26A, the bumper 317 is expanded or neutral and both of the spacers 314are compressed. In state “D” shown in FIG. 26B, the bumper 317 iscompressed while the central spacer 314 expands to a neutral or nearneutral state, while the end spacer 314 remains compressed.

With reference to FIGS. 27A and 27B, a soft stabilization assembly isshown that is substantially similar to that shown in FIGS. 25A and B,with the exception that there is no end spacer 314 and an alternativeplate or fixer/blocker member Q′ fixes the cord or cord bundle 310′ atan end of the assembly adjacent one of the bone screws 75″. FIGS. 27Aand B illustrates the assembly in two states of dynamic stabilizationthat occur without the cord 310′ changing length. In state “E” shown inFIG. 27A, the spacer 314A is compressed, while the bumper 317 is allowedto expand to a neutral state. In state “F” shown in FIG. 27B, the bumper317 is compressed and the spacer 314A expands.

With reference to FIGS. 28-32 , the reference numeral 1001 generallydesignates a non-fusion, soft or dynamic longitudinal stabilizationconnector assembly of the invention. The illustrated assembly 1001includes the following components: an elongate bendable and flexiblecore in the form of a cord 1004; at least one cannulated spacer 1006; anelastic bumper 1008; and a fixing structure or blocking member, such asa crimping structure 1010. The assembly 1001 is shown with a pair ofopen monoaxial bone screws, generally 1012, the assembly 1001 extendingsubstantially linearly along a central axis A in FIG. 30 , for example.For purposes of this application, the identical bone screws 1012 areidentified as 1012A and 1012B as the one bone screw 1012A cooperateswith a first locking and cord pressing closure top 1014 and the otherbone screw 1012B cooperates with a second locking limited travel closuretop 1015 that allows for slip or slide of the cord 1004 within the bonescrew 1012B. The closure tops 1014 and 1015 are substantially similar toone another with the exception that the top 1015 is sized and shaped tobottom out on a lower seating surface 1017 of a run-out of an innerguide and advancement structure 1018 of the bone screw 1012 that mateswith the outer guide and advancement structure of the closure top 1014or the closure top 1015. The closure top 1014 further includes an end orbottom portion 1019 that extends beyond the run-out seating surface 1017and abuts against and fixes the cord to the bone screw. The guide andadvancement run-out seating surface 1017 is best shown and describedwith respect to an alternative bone screw 1112 and 1112′ described ingreater detail below with reference to FIGS. 33-41 . Also, as will bedescribed in more detail below, the bone screw 1012A cooperates with theclosure top 1014 to fix a portion of the cord 1004 to the bone screw1012A while the bone screw 1012B engages and fixes the closure top 1015to the screw 1012B to capture a portion of the cord 1004 within the bonescrew 1012B, but allow for sliding movement of the cord 1004 withrespect to the bone screw 10123. The elongate inner cord core 1004 isslidingly received within the spacer 1006 and the bumper 1008, andinitially within the blocker or crimping structure 1010, as will bedescribed in greater detail below. The cord 1004 is eventually tensionedand fixed in such tensioned state by the crimping structure or blocker1010 and the bone screw 1012A. In other embodiments according to theinvention, the structure 1010 may include a threaded aperture (notshown) and further include a cooperating set screw in addition to or inlieu of crimping. In such embodiments, as shown in other embodiments ofthe invention described in more detail below, the set screw rotatablymates with the structure 1010 at the threaded aperture and is rotateduntil a bottom surface of the screw presses against and, in someembodiments, penetrates the cord, fixing the cord within the structure1010. As will be described in greater detail below, when fully assembledand all the components are fixed in position as shown in FIGS. 28 and 32, for example, the cord 1004 is in tension, the spacer 1006 may be incompression or in a neutral state, and the bumper 1008 is incompression.

It is noted that in other embodiments according to the invention, boththe bone screws 1012A and 1012B may be mated with a locking limitedtravel closure top 1015 and at least one additional blocker or crimpingstructure is included generally opposite the crimping structure 1010 inthe overall assembly to result in a cord that is tensioned along theassembly but in sliding cooperation with two or more bone anchors ofsuch assembly. It is also noted that additional spacers 1006 and bonescrews 1012 cooperating with closure tops 1015 may be utilized accordingto the invention, providing longer assemblies of the invention with oneof the spacers 1006 placed between each bone screw and the bumper 1008and the crimping structure 1010 placed at one or both ends of suchassembly next to a bone screw 1012 cooperating with a closure top 1015or two such closure tops 1015. Also, as described in greater detailbelow, bone screws, spacers, bumpers and crimping structures or otherblockers of the invention may be sized, shaped and used with hard ordeformable rods and bars, alternatively to the cord 1004.

Although the screws 1012 are illustrated, it is noted that the assembly1001 may cooperate with a variety of bone screws and other bone anchors,including closed bone screws, hinged bone screws, polyaxial bone screws,with or without compression inserts, and bone hooks that may in turncooperate with a variety of closure structures having threads, flanges,or other structure for fixing the closure structure to the bone anchor,and may include other features, for example, external or internaldrives, break-off tops and inner set screws. A closed bone anchor withor without a set screw may also be used in the invention to capture thecord 1004 in sliding, but not fixed engagement. The bone anchors,closure structures and the connecting member 1001 are then operablyincorporated in an overall spinal implant system for correctingdegenerative conditions, deformities, injuries, or defects to the spinalcolumn of a patient.

The connecting member assembly 1001 is elongate, with the inner core1004 being any soft elongate material including, but not limited tocords, threads, strings, bands, cables or fibers that may be single ormultiple strands, including twisted, braided or plaited materials. Theillustrated cord 1004 has a substantially uniform body 1020 ofsubstantially circular cross-section, a first end 1022 and an opposedsecond end 1024, the cord 1004 being cut to length as required by thesurgeon. Initially, the cord 1004 is typically of a length longer thanshown in the drawings to allow for gripping of the cord 1004 duringassembly with the other components of the assembly 1001 and also fortensioning and attachment to the bone screws 1012A and 1012B as will bedescribed in greater detail below. The cord 1004 may be made from avariety of materials, including polyester or other plastic fibers,strands or threads, such as polyethylene-terephthalate. The cord 1004may be placed under axial tension prior to final installation betweenthe bone screws 1012A and 1012B, for example by being tensioned alongthe axis A for a selected time to lengthen and otherwise deform the cord1004 during a primary creep stage. After the cord 1004 reaches asecondary or steady-state creep, further tension is placed on the cord1004 in preparation for fixing between the bone screw 1012A and thecrimping structure 1010 as will be described in greater detail below. Itis noted that the cord 1004 typically does not illustrate elasticproperties, such as any significant additional lengthening with axialtraction, after the assembly 1001 is operatively assembled within ahuman body, but the elastic bumper 1008 will allow for relative movementbetween the fully stretched cord 1004 and the bone screw 1012B inresponse to spinal flexion, extension and any movement that may draw thebone screw 1012B away from the bone screw 1012A.

With particular reference to FIGS. 28, 29 and 32 , the spacer 1006 issized and shaped to be slidingly received over the cord 1004 and may bemade from a variety of elastic and more rigid materials, including, butnot limited to natural or synthetic elastomers such as polyisoprene(natural rubber), and synthetic polymers, copolymers, and thermoplasticelastomers, for example, polyurethane elastomers such aspolycarbonate-urethane elastomers. In order to have low or no weardebris, the spacer 1006 inner and side surfaces may be coated with anultra thin, ultra hard, ultra slick and ultra smooth coating, such asmay be obtained from ion bonding techniques and/or other gas or chemicaltreatments. The illustrated spacer 1006 has an external substantiallycylindrical outer surface 1028 and an internal substantially cylindricalsurface 1030. The surface 1030 is sized and shaped to closely cooperateand fit about the cord 1004 and yet allow some sliding movement of thecord 1004 with respect to the spacer 1006 along the axis A. The spacer1006 includes opposed substantially planar and annular end surfaces 1032and 1034 that are sized and shaped to abut against planar surfaces ofthe bone screws 1012A and 1012B, respectively. When initially assembledwith the other components of the connecting member assembly 1001, thesurfaces 1032 and 1034 are substantially perpendicular to the axis A. Itis foreseen that in some embodiments, the spacer 1006 may be of smalleror larger outer circular cross section, or of a square, rectangular orother inner or outer cross-section including other curved or polygonalshapes. The spacer 1006 may further include one or more compressiongrooves that allow for some additional compression of the spacer 1006when pressed upon in an axial direction between the bone anchors 1012Aand 1012B. Typically, such a compression groove is substantially uniformand circular in cross-section, being formed in the external surface 1028and extending radially toward the internal surface 1030. The spacer canhave an off-axial lumen.

Also with particular reference to FIGS. 28, 29 and 32 , the elasticbumper 1008 is annular and includes an outer cylindrical surface 1040,an inner cylindrical surface 1042, an end surface 1044 and an opposedend surface 1046. The illustrated bumper 1008 further includes acompression groove 1048 that allows for some additional compression ofthe bumper 1008 when pressed upon in an axial direction A between thebone anchor 1012B and the crimping ring 1010. The compression groove1048 is substantially uniform and circular in cross-section, beingformed in the external surface 1040 and extending radially toward theinternal surface 1042. Bumpers of the invention may include one, none ora plurality of compression grooves. The inner cylindrical surface 1042forms a bore sized and shaped for closely receiving the cord 1004therethrough as shown, for example, in FIG. 32 . The end surfaces 1044and 1046 are substantially parallel to one another, but can also benon-parallel.

The bumper 1008 may be made from a variety of elastic materials,including, but not limited to natural or synthetic elastomers such aspolyisoprene (natural rubber), and synthetic polymers, copolymers, andthermoplastic elastomers, for example, polyurethane elastomers such aspolycarbonate-urethane elastomers. The bumper 1008 is typically shorterin length and more elastic than the spacer 1006, but may be equal to orlonger than the spacer and of the same, greater or lesser durometer thanthe spacer 1006. In order to have low or no wear debris, the bumper 1008inner and side surfaces may also be coated with an ultra thin, ultrahard, ultra slick and ultra smooth coating, such as may be obtained fromion bonding techniques and/or other gas or chemical treatments.

The fixing structure or blocker, illustrated as the crimping structureor ring 1010 is substantially cylindrical and includes an outer surface1050 and an inner surface 1052 forming a substantially cylindricalthrough bore that opens at planar end surfaces 1054 and 1056 andoperatively extends along the axis A. The crimping ring 1010 is sizedand shaped to receive the elongate cord 1004 through the inner surface1052. The crimping ring 1010 further includes a pair of opposed crimp orcompression grooves 1058 that are pressable and deformable inwardlytoward the axis A upon tensioning of the cord 1004 and pre-compressionof the bumper 1008 during assembly of the assembly 1001. The crimpingring 1010 is preferably made from a stiff, but deformable material,including metals and metal alloys. It is foreseen that in lieu of oraddition to the crimping surface, the blocker could include a threadedaperture and a mating locking set screw for engaging and pressing intothe cord 1004.

The bone screws generally 1012, and in particular the illustrated screws1012A and 1012B are open, fixed, monoaxial screws, each having an uppercord receiving portion 1062 integral with a threaded bone attachmentportion or shank 1064. The portion 1062 further includes a substantiallyU-shaped channel 1066 for closely receiving the cord 1004 therethrough,the channel 1066 further having an upper closure top receiving portionwith the helically wound guide and advancement structure 1018 thereonfor receiving and mating with the closure top 1014 or the closure top1015. The upper, receiving portion 1062 further includes opposed,substantially parallel side surfaces 1070 that abut against sidesurfaces of the spacer 1006 or the bumper 1008. However, it is foreseenthat according to the invention, other embodiments of the invention mayinclude side surfaces 1070 that angle away or towards one another forlordosing or kyphosing controlling embodiments as previously describedin applicant's application U.S. Ser. No. 11/328,481, incorporated byreference herein.

To provide a biologically active interface with the bone, the threadedshanks 1064 of the bone screws 1012A and 1012B may be coated,perforated, made porous or otherwise treated. The treatment may include,but is not limited to a plasma spray coating or other type of coating ofa metal or, for example, a calcium phosphate; or a roughening,perforation or indentation in the shank surface, such as by sputtering,sand blasting or acid etching, that allows for bony ingrowth orongrowth. Certain metal coatings act as a scaffold for bone ingrowth.Bio-ceramic calcium phosphate coatings include, but are not limited to:alpha-tri-calcium phosphate and beta-tri-calcium phosphate (Ca₃(PO₄)₂,tetra-calcium phosphate (Ca₄P₂O₉), amorphous calcium phosphate andhydroxyapatite (Ca₁₀(PO₄)₆(OH)₂). Coating with hydroxyapatite, forexample, is desirable as hydroxyapatite is chemically similar to bonewith respect to mineral content and has been identified as beingbioactive and thus not only supportive of bone ingrowth, but activelytaking part in bone bonding.

With particular reference to FIGS. 28, 29 and 32 , the closurestructures 1014 and 1015 can be any of a variety of different types ofclosure structures for use in conjunction with the present inventionwith suitable mating structure on the interior surface of the receiver1062 of the open bone screws 1012. The illustrated closure structures1014 and 1015 are each rotatable between the spaced arms forming thereceiver 1062 and are substantially cylindrical, including an outerhelically wound guide and advancement structure in the form of a flangeform that operably joins with the guide and advancement structure 1018.A driving tool 1072 illustrated in FIG. 30 is sized and shaped forengagement with an internal drive feature 1074 and is used for bothrotatable engagement and, if needed, disengagement of the closure 1014and/or closure 1015 from one of the receivers 1062. The internal drivefeature 1074 may take a variety of forms and may include, but is notlimited to, a hex shape (as shown), TORX or other features or apertures,such as slotted, tri-wing, spanner, two or more apertures of variousshapes, and the like. As stated above, the closure 1014 and the closure1015 are substantially identical with the exception of a height or depthdimension in the form of the portion or knob 1019 that extendsoperatively perpendicular to the axis A. The closure structure 1014 thatincludes the portion 1019 is sized and shaped to be long enough tocompress against the cord 1004 and frictionally fix the cord 1004 in thereceiver 1062 when fully seated and mated with the guide and advancementstructure 1018. (See, e.g., FIG. 41 that shows a similar closure 1114that abuts against a run-out seat 1117′ and has an extended portion 1119for pressing down on a core, such as a cord or rod or bar). Theillustrated closure top 1014 may further include points or projectionsfor piercing into the cord 1004 to provide enhanced contact and fixingof the cord 1004 to the receiver 1062. The closure 1015 is sized andshaped to be long enough to fully seat within the receiver 1062 and matewith the guide and advancement structure 1018 run-out seating surface1017 in order to fix the closure 1015 in the bone screw and capture thecord 1004 within the receiver 1062. However, the closure 1015 is tooshort to fix the cord 1004 against the receiver 1062. Rather, when theclosure 1015 is fully seated and mated in the receiver 1062, the cord1004 remains in slidable relationship with the bone screw 1012B and isnot fixed against a surface of the receiver 1062. See, e.g., FIG. 36that shows a similar closure 1115 that abuts against a run-out seat 1117and is spaced from or in sliding engagement with a core, such as a cordor cable or rod or bar. In other embodiments, the closure 1115 mayinclude an upper stop or cap portion 1187 (shown in phantom) and thereceiver run-out seat 1117 need not extend inwardly to the extent shownin FIG. 36 . In such an alternative embodiment, the cap portion 1187abuts the receiver top surface which keeps the closure in a desiredlocation spaced from or in sliding engagement with a cord, cable, rod orbar.

In use, the two bone screws 1010 and 1012 are implanted into vertebraefor use with the dynamic connecting member 1001. Each vertebra may bepre-drilled to minimize stressing the bone. Furthermore, if a cannulatedbone screw shank and/or closure top is utilized (as illustrated), eachvertebra will have a guide wire or pin (not shown) inserted therein thatis shaped for the bone screw cannula of the bone screw shank 1064 andprovides a guide for the placement and angle of the shank 1064 withrespect to the cooperating vertebra. A further tap hole may be made andthe shank 1064 is then driven into the vertebra by rotation of a drivingtool (not shown) that engages a driving feature on or near the topportion 1062 of the screw 1012. It is foreseen that the screws 1012A and1012B and the dynamic connector 1001 can be inserted in a percutaneousor minimally invasive surgical manner.

With particular reference to FIGS. 29-31 , the dynamic connectorassembly 1001 is assembled by inserting the cord 1004 into the throughbore formed by the internal surface 1030 of the spacer 1006. Also asindicated in FIGS. 29 and 30 , the cord 1004 is first received into theU-shaped opening 1066 of the open bone screw 1012A and the U-shapedopening 1066 of the bone screw 1012B, with the spacer 1006 beingdisposed between facing surfaces 1070 of bone screws 1012A and 10123.The closure top 1014 is rotated and driven into the receiver 1062 of thebone screw 1012A until the closure top 1014 frictionally engages thecord 1004 and fixes the cord 1004 to the screw 1012A. Before or afterthe closure top 1014 is tightened, the closure top 1015 may be insertedand rotated into the receiver 1062 of the bone screw 1012B until the top1015 is fully seated and engaged with such receiver run-out surface1017, capturing but not fixing the cord 1004 to the bone screw 1012B.The bumper 1008 is threaded along the cord 1004 with the cord slidingthrough the through-bore formed by the inner surface 1042 until thebumper face 1044 abuts against the surface 1070 of the bone screw 10123located opposite the spacer 1006. The crimping structure or blocker 1010is threaded along the cord 1004 with the cord sliding through thethrough-bore formed by the inner surface 1052 until the crimper face1054 abuts against the bumper face 1046.

The cord 1004 is tensioned and the bumper 1008 is compressed against thebone screw 1012B by axial movement of the crimping structure 1010against the bumper 1008, squeezing the bumper 1008 between the bonescrew 1012B and the crimping structure 1010. The spacer 1006 also may becompressed at this time. With particular reference to FIG. 31 , acrimping tool 1080 is used to frictionally attach the tensioned cord1004 to the crimping structure 1010, thereby holding the cord 1004 intension between the bone screw 1012A and the crimping structure 1010 andalso compressing the bumper 1008 against the bone screw 1012B.

The resulting connecting member assembly 1001 is loaded with the cord1004 in tension and the bumper 1008 and optionally the spacer 1006 incompression. The assembly 1001 is thus substantially dynamically loadedand oriented relative to the cooperating vertebra, providing relief(e.g., shock absorption) and protected movement in response to spinalflexion and extension, and further responding to distractive ortensioning forces as well as to compressive forces.

If removal of the dynamic connector assembly 1001 from the bone screws1012A and/or 1012B is necessary, or if it is desired to release theassembly 1001 at a particular location, disassembly is accomplished byusing the driving tool 1072 with a driving formation cooperating withthe closure tops 1014 and 1015 to rotate and remove the closure top fromthe bone screw 1012A and/or 1012B. Disassembly is then accomplished inreverse order to the procedure described previously herein for assembly.

With reference to FIGS. 33-36 , a bone screw 1112 is illustrated that isidentical to the bone screw 1012 of the assembly 1001 with the exceptionthat the U-shaped channel 1066 formed by inner surfaces of the screw1012 has been replaced with a substantially rectangular channel 1166formed by opposed planar surfaces 1167 and a bottom planar surface 1168.The bone screw 1112 has a receiver 1162 and a shank 1164, the receiver1162 having a discontinuous guide and advancement structure 1118 that isformed in the opposed surfaces 1167. The bone screw 1112 may be utilizedin an assembly 1101 substantially similar to the assembly 1001 thatincludes a cord 1104 identical or substantially similar to the cord 1004and further includes the spacer 1006, elastic bumper 1008, crimpingstructure 1010 of the assembly 1001 previously described herein. Becauseof the squared off shape of the channel 1166, the bone screw 1112 mayalso be readily used with other longitudinal connecting members, such asthe bar 1105 shown in FIG. 34 and the rod 1106 shown in FIG. 37 . Thebar 1105 and the rod 1106 may be made of a variety of materials rangingfrom deformable plastics to hard metals, depending upon the desiredapplication. Thus, bars and rods of the invention may be made ofmaterials including, but not limited to metal, metal alloys or othersuitable materials, plastic polymers such as polyetheretherketone(PEEK), ultra-high-molecular weight-polyethylene (UHMWP), polyurethanesand composites, including composites containing carbon fiber, natural orsynthetic elastomers such as polyisoprene (natural rubber), andsynthetic polymers, copolymers, and thermoplastic elastomers, forexample, polyurethane elastomers such as polycarbonate-urethaneelastomers. Whether the longitudinal connecting member of the inventionis a cord, rod or bar; hard-surfaced or soft and deformable; or elasticor non-elastic, the combination of a limited travel closure top thatallows the connecting member some movement within the bone screw furthercooperating with a bumper and a connector holding structure or blockersuch as the crimping structure 1010, advantageously allows for limitedmovement of the connector with respect to the bone screw, creating adynamic connection between spinal assembly and cooperating vertebrae.

With particular reference to FIGS. 35 and 36 , the bone screw 1112 guideand advancement structure 1118 that receives and mates with the limitedtravel closure 1115 includes a run-out aperture or groove partiallydefined by a bottom or lower seating surface 1117 sized and shaped forfrictional engagement with a portion of the closure 1115. As shown inFIG. 36 , the closure 1115 minor diameter is slightly bigger than therun-out groove so the closure 1115 abuts against the surface 1117 whendriven downward into the receiver. The seating surface 1117 terminatesat the opposed planar surfaces 1167.

With further reference to FIG. 33 , the bone screw receiver 1162 furtherincludes opposed, substantially parallel outer side surfaces 1170. It isforeseen that according to the invention, other embodiments of theinvention may include side surfaces that angle away or towards oneanother for lordosing or kyphosing controlling embodiments as previouslydescribed in applicant's application U.S. Ser. No. 11/328,481, thedisclosure of which is incorporated by reference herein. It is alsonoted that the bone screw 1112 is identical or substantially similar tothe bone screws described in described in detail in Applicant's U.S.patent application Ser. No. 12/584,980, the disclosure of which isincorporated by reference herein.

Specifically, the closure top 1115 is substantially cylindrical andincludes a top surface 1180, a bottom surface 1182, a drive feature 1184formed in the top surface 1180 and an outer guide and advancementstructure 1186 sized and shaped to mate with the guide and advancementstructure 1118 of the bone screw 1112. A cylindrical surface 1188represents the minor diameter of a major portion of the closure 1115.The illustrated closure top 1115 is rotatable between the spaced armsforming the receiver 1162 of the screw 1112. The illustrated helicallywound guide and advancement structure 1186 is in the form of a flangeform that operably joins with respective guide and advancement structure1118. A driving tool or tools (not shown) sized and shaped forengagement with the internal drive feature 1184 is used for bothrotatable engagement and, if needed, disengagement of the closure 1115from the screw 1112. The internal drive feature 1184 may take a varietyof forms and may include, but is not limited to, a hex shape, TORX orother features or apertures, such as slotted, tri-wing, spanner, two ormore apertures of various shapes, and the like.

With particular reference to FIG. 36 , the closure top 1115 is sized andshaped to cooperate with the run-out surface 1117 to lock the closure1115 on the bone screw 1112 independent of any pressure being placed bythe closure 1115 on the cord 1104. Due to the size of the surface 1188,the bottom surface 1182 near the surface 1188 forms a radially extendingshelf or abutment seat. When the closure 1115 is tightened by rotationinto the screw 1112, the bottom 1182 abuts against the surface 1117,allowing the closure to be tightened in the screw receiver 1162independent of whatever size cord 1104 or other core, such as the bar1105 might be. Stated in another way, the closure 1115 is prohibitedfrom entering the space between the planar surfaces 1167 that supportthe cord 1104 or other core therebetween. Thus, it is not possible forthe closure 1115 to press upon the cord 1104, allowing such cord toslide between the closure top 1115 and the surfaces 1167 and 1168. Alsoshown in FIG. 36 is an alternative feature or cap portion 1187 (shown inphantom) that may be used in lieu of providing the surface 1117 of thebone screw 1112. In such an embodiment, the cap portion 1187 of theclosure 1115 abuts against a top surface of the bone screw 1112 when theclosure 1115 is fully mated and locked with the bone screw 1112 guideand advancement structure 1118, prohibiting the closure 1115 from beingwound down into contact with a cord or other inner core member.

With reference to FIGS. 37-41 , a bone screw 1112′ is illustrated thatis identical to the bone screw 1112, having a receiver 1162′, a shank1164′, a rectangular channel 1166′ formed by opposed planar surfaces1167′ and a bottom surface 1168′, the same or substantially similar tothe receiver 1162, shank 1164, channel 1166, opposed planar surfaces1167 and bottom surface 1168 previously described herein with respect tothe bone screw 1112. Further, the bone screw 1112′ includes a lower seat1117′ of a guide and advancement structure 1118′ and side surfaces1170′, the same or similar to the lower seat 1117, guide and advancementstructure 1118 and side surfaces 1170 of the bone screw 1112. The bonescrew 1112 is shown with the plastic, deformable rod 1106 and a lockingclosure top 1114 having a lower extension portion 1119 that is the sameor similar to the closure top 1014 having the extended bottom portion1019 previously described herein with respect to the assembly 1001.

The closure top 1114 is substantially cylindrical and includes a topsurface 1180′, a bottom surface 1182′, a drive feature 1184′ formed inthe top surface 1180′ and an outer guide and advancement structure 1186′sized and shaped to mate with the guide and advancement structure 1118′of the bone screw 1112′. A cylindrical surface 1188′ represents theminor diameter of a major portion of the closure 1114. The illustratedclosure top 1114 is rotatable between the spaced arms forming thereceiver 1162′ of the screw 1112′. The illustrated helically wound guideand advancement structure 1186′ is in the form of a flange form thatoperably joins with respective guide and advancement structure 1118′. Adriving tool or tools (not shown) sized and shaped for engagement withthe internal drive feature 1184′ is used for both rotatable engagementand, if needed, disengagement of the closure 115 from the screw 1112.The internal drive feature 1184 may take a variety of forms and mayinclude, but is not limited to, a hex shape, TORX or other features orapertures, such as slotted, tri-wing, spanner, two or more apertures ofvarious shapes, and the like.

With particular reference to FIG. 41 , the closure top 1114 is sized andshaped to cooperate with the run-out surface of the guide andadvancement structure 1118′ to lock the closure 1114 on the bone screw1112′ independent of any pressure being placed by the closure 1114 onthe deformable rod 1106. In the illustrated embodiment, the closure 1114includes a second cylindrical surface 1190 located adjacent to and belowthe surface 1188′ that defines the minor diameter of most of the closure1114. The second cylindrical surface 1190 has a second diameter smallerthan the minor diameter of the surface 1188′. The outer surface 1190partially defines the extended portion 1119. The surface 1190 is locatednear the bottom surface 1182′ of the closure 1114 that contacts andpresses against the deformable rod 1106 or other longitudinal connectingmember core located within the bone screw receiver 1162′ duringoperation. As shown in FIGS. 39 and 41 , the portion 1119 pressesagainst and partially deforms the rod 1106. A radially extending shelfor abutment seat 1192 is formed between the cylindrical surface 1188′and the cylindrical surface 1190. When the closure 1114 is tightened byrotation into the screw 1112′, the seat 1192 abuts against the surface1117′, allowing the closure to be tightened in the screw receiver 1162′independent of the rod 1106. The rod 1106 is pressed upon and held inplace by the bottom surface 1182′ of the screw, with some deformation ofthe rod 1106 being acceptable and even desirable. In the illustratedembodiment, some of the rod material is allowed to flow up into an innerbore 1195 of the closure 1114. However, because of the cooperationbetween the seat 1192 and the screw surface 1117′, the rod 1106 isprotected against over-deformation or crushing that might lead toinstability and failure. Furthermore, if the rod 1106 exhibits creep orother deformation during operation, loosening or lessening of thecontact engagement between the closure bottom surface 1182′ and the rod1106 will not result in loosening of the closure 1114 from the screw1112′.

With reference to FIGS. 42 and 43 , an assembly 1201′ according to theinvention is illustrated that provides for dynamic stabilization similarto the assembly 1001 utilizing polyaxial bone screws. The illustratedassembly 1201 includes a solid, hard-surfaced rod 1204, a spacer 1206,an elastic bumper 1208, a crimping structure 1210 and a pair ofpolyaxial bone screws 1212A and 1212B. The bone screws 1212A and 1212Bare identical or substantially similar to those described in Applicant'sU.S. patent application Ser. No. 12/229,207, filed Aug. 20, 2008entitled “Polyaxial Bone Anchor Assembly With One-Piece Closure,Pressure Insert and Plastic Elongate Member,” (hereafter, the '207application), the disclosure of which is incorporated by referenceherein. A closure top 1214 fixes the rod 1204 in the bone screw 1212Aand a closure top 1215 captures the rod 1204 in the bone screw 1212B,but a bottom surface 1282 thereof does not fix the rod 1204 with respectto the bone screw 1212B as illustrated in FIG. 43 . (See, e.g., FIGS.15-18 of the '207 application for illustrations of fixing of a rigid ordeformable rod with a bone screw the same or similar to the screw1212A). Each screw 1212A and 1212B further includes a receiver 1203 forslidingly pivotally receiving a bone screw shank upper portion, and alower pressure insert 1205 having surfaces for engaging the shank upperportion and surfaces for closely receiving the rod 1204. With referenceto FIG. 43 , the closure top 1215 lower surface 1282 engages upper armsurfaces 1283 of the pressure insert 1205 to capture the rod 1204 andlock the polyaxial mechanism of the bone screw 1212B. Thus, the capturedrod 1204 is in sliding engagement with the screw 1212B. The spacer 1206,elastic bumper 1208 and the blocker crimping structure 1210 are the sameor similar in form and function to the spacer 1006, bumper 1008 andcrimping structure 1010 previously described herein with respect to theassembly 1001, with the crimping structure 1210 directly engaging therod 1204. In alternative embodiments, a cord or deformable rod may beutilized in lieu of the illustrated rigid rod 1204. The pressure insert1205 may also be configured to receive a square or rectangular bar.Also, FIG. 43 illustrates an alternative cap closure 1215B (shown inphantom) having an upper outer portion that extends about a top portionof the receiver 1212B and cooperates with a lip thereof to lock theclosure to the receiver 1212B at a desired position with the lowersurface 1282 of the closure pressing down on the pressure insert 1205 tolock the polyaxial mechanism without pressing of the rod, cord or otherlongitudinal connecting member captured between the insert and theclosure.

With reference to FIGS. 44-49 , the reference numeral 2001 generallydesignates another non-fusion, soft or dynamic longitudinalstabilization connector assembly of the invention. The illustratedassembly 2001 includes the following components: an elongate bendableand soft, flexible core in the form of a cord 2004; at least onecannulated spacer 2006; an elastic bumper 2008; and a fixing structureor blocking member, such as a blocker 2010 with cooperating set screw2011. The assembly 2001 is shown with three open monoaxial bone screws,generally 2012, the assembly 2001 extending substantially linearly alonga central axis AA. The assembly 2001 is also shown with two differentclosure tops for cooperating with the bone screws 2012: a cord grippingclosure top 2014 and a non-gripping closure top 2015. The bone screws2012 and closure tops 2014 and 2015 are also shown in greater detail inFIG. 60 . Furthermore, the blocker 2010 and cooperating set screw 2011are shown in greater detail in FIGS. 55-58 . The spacer 2006 is alsoshown in FIG. 59 . It is noted that the spacers 2006 and bumper 2008 areshown as being made from a transparent plastic. However, in someembodiments of the invention, spacers and bumpers may also be opaque.

The cord 2004 is identical or substantially similar in form, functionand materials to the cord 1004 previously described herein and the cordor cord bundles previously described herein with respect to the assembly1. Similarly, the spacers 2006 are the same or similar in form, functionand materials to the spacers 1006 and the spacers 214 and 314 previouslydescribed herein with the exception that, as best shown in FIG. 59 , thespacer 2006, although tubular, is also shaped to provide more spacermaterial below the cord 2004. Spacers of the invention could also becylindrical or have other shapes. The bumper 2008 is a cylindrical tubeand is the same or similar in form, function and materials as the bumper1008 previously described herein.

The blocker 2010 and set screw 2011 combination functions similarly tothe crimping blocking member 1010, for example, previously describedherein and may also be made from the same hard materials. Rather thankcrimping the blocker 1010 to attach the blocker to the cord, the blocker2010 is attached to the cord 2004 by action of the set screw 2011 beingrotated and moved downwardly against the cord 2004 until the cord 2004is fixed against the blocker 2010. With reference to FIGS. 55-58 , theblocker 2010 advantageously includes opposed grooves 2020 that allow forease in holding the blocker 2010 during assembly and also duringsurgery. The blocker 2010 advantageously has a more narrow profile asmeasured along the length of the cord 2004 than the crimping blocker1010 previously described herein as the set screw 2011 rather thanblocker material is required for pressing against the cord 2004. Theblocker 2010, bumper 2008, bone screws 2012 and spacers 2006advantageously include planar end surfaces that are also space savingand provide easy compatibility, changeability and substitution betweenthe assembly components.

The open bone screws 2012 are the same or similar to the bone screws1012 previously described herein. Each bone screw 2012 is compatiblewith the gripping closure top 2014 that includes a lower projection 2030for pressing against the cord 2004 and also compatible with the slippingclosure top 2015 that does not have a projection 2030, but otherwiselocks in the screw 2012 in a manner previously described herein withrespect to the screws 1012 and the closure top 1015. The bone screw 2012also cooperates with a closure top 2016 that further includes a point ora point and rim for cooperating with a hard rod as shown, for example,in FIG. 50 .

With further reference to FIGS. 44 and 45 , the assembly 2001 is shownin a nominal state, as, for example, the assembly would be in after thecord 2004 is tensioned (in some embodiments, after the cord 2004 has hadsome extension after creep and wherein the cord 2004 may have beenre-tensioned and recaptured at either the bumper 2010 or the closure top2014). As shown, tensioning of the cord 2004 also results in somecompression placed on the bumper 2008 as well as the two spacers 2006.As best shown in FIG. 45 , the cord 2004 is in tension between theblocker 2010 and the end screw 2012 that has the closure top 2014pressing against the cord 2004. The cord 2004 is free to slide withrespect to the other two screws 2012 that are mated with the slipclosure tops 2015. With reference to FIGS. 46 and 47 , the assembly 2001is shown responding to a compressive force on vertebrae (not shown)attached to the three bone screws 2012. In such instance, the elasticbumper 2008 is allowed to expand to a near neutral state, with the cord2004 and spacers 2006 moving in response to such force. With referenceto FIGS. 48 and 49 , the assembly 2001 is shown responding to adistractive force, pushing the bumper 2008 into further compression andresulting in only a slight gap between the spacers 2006 and the bonescrews 2012.

With reference to FIG. 50 , the assembly 2001 has been modified tocreate the assembly 2001′ wherein the cord 2004, the spacers 2006, thebumper 2009 and the blocker 2010 are replaced with a hard rod 2040 andeach of the bone screws 2012 are attached to the rod 2040 with theclosure top 2016.

FIGS. 51 and 52 illustrated an alternative assembly 2002 wherein a cord2004 is attached to a hard rod 2040 using a rod/cord connector orblocker 2050 that cooperates with a set screw 2051 and a set screw 2052.The rod/cord blocker 2050 is sized and shaped like a double-wide blocker2010 with a first bore for slidingly receiving the cord 2004 at an endthereof communicating with a larger bore for receiving the rod 2040 atan end thereof. Running perpendicular to the cord and rod through boreare two threaded apertures allowing for connection and capture of thecord 2004 by rotation and downward movement of the longer set screw 2041and connection and capture of the hard rod 2040 by downward rotation ofthe shorter set screw 2052 (see also FIG. 61 ). It is noted that the setscrew 2051 and the set screw 2011 may be identical. The cord istensioned between the set screw 2051 and rod/cord connector 2050 and theblocker 2010 with set screw 2011. A bumper 2008 is located next to theblocker and is also adjacent to a closed bone screw 2012′ that will bedescribed in greater detail below. On the other side of the screw 2012′is a small on-axis tubular spacer 2006′ (that will also be described inmore detail below) that in turn is adjacent to the rod/cord blocker2050. The hard rod 2040 is then shown attached to three bone screws2012, each cooperating with a closure top 2016. Thus, the cord 2004 isin slidable cooperating with the bone screw 2012′, providing some softstabilization in an otherwise more hard or rigid assembly 2002.

With reference to FIGS. 53 and 54 , a soft stabilization connector 2003is illustrated that includes the cord 2004, bumper 2008, blocker 2010and bone screws 2012 previously described herein. In this embodiment thespacers 2006 of the assembly 2001 are replaced with lordotic spacers2006′. The spacers 2006′ are identical to the spacers 2006 with theexception of planar end surfaces 2060 that are formed or cut at anangle, resulting in a desired lordotic arrangement of the assemblycomponents.

With reference to FIGS. 62-63 , another soft stabilization connector3001 is shown. The assembly 3001 is identical to the assembly 2001 withthe exception that tubular on-axis spacers 2006′ replace the off-axisspacers 2006 and closed screws 2012′ replace the open screws 2012. Theclosed screw 2012′ with cooperating set screw 2011′ is shown in greaterdetail in FIGS. 69-71 . The closed screws 2012′ differ from the openscrews 2012 in that the closed screws 2012′ cooperate with the smallerset screw 2011′ (that may be identical to the blocker set screw 2011),requiring threading of the cord 2004 through a through bore 3010 of thescrew 2012′ as opposed to the open channel provided by the open screw2012 that receives the cord 2004 through an upper opening of thechannel. The closed screws 2012′ however, advantageously allow forcomplete capture of the cord 2004 as well as slidable movement betweenthe cord 2004 and the screw 2012′. Thus, no set screw is needed when aslidable relationship between the cord 2004 and the screw 2012′ isdesired.

The assembly 3001 shown in FIGS. 62 (A-C) and 63 (A-C) includes apre-tensioned cord 2004 fixed between the blocker 2010 and the bonescrew 2012′ that is cooperating with the set screw 2011′. The cord isslidable with respect to the other two bone screws 2012′ that are notcooperating with any set screws 2011′. Pre-tensioning of the cord 2004also results in some compression of the bumper 2008 and the two spacers2006′. Also, with further reference to FIGS. 62 (A-C- and 63 (A-C),three states or positions of the assembly components are shown in thesefigures. In the state or position identified by the letter X in FIGS.62A and 63A, a distracted state or position of the vertebrae (not shown)is demonstrated wherein the bumper 2008 is fully compressed while thespacers 2006′ are axially extended to a near neutral or nominal state.In the state or position identified by the letter Y in FIGS. 62B and63B, the vertebrae (not shown) are compressed together, resulting in thebumper 2008 expanding to a near neutral state with the spacers 2006′being fully compressed. The state or position identified by the letter Zin FIGS. 62C and 63C is a nominal or neutral position in which thebumper 2008 and the spacers 2006′ are slightly compressed and areholding the cord 2004 in a steady-state tension.

With reference to FIGS. 64 and 65 , another embodiment of a softstabilization connector 3002 is shown that includes a blocker 2010/setscrew 2011 combination on either side thereof, the blockers holding apre-tensioned cord 2004 in tension along and with respect to threeclosed bone screws 2012′, none of which are cooperating with a setscrew. Thus, the cord 2004 is in slidable relationship with each of thethree bone screws 2012′. Located adjacent each blocker 2010 is a bumper2008 and on-axis spacers 2006′ are located between each of the screws2012′. It is noted that one or both of the bumpers 2008 may be omittedin certain embodiments.

With reference to FIGS. 66-68 , another embodiment of a softstabilization connector 3002′ is shown that includes a blocker 2010/setscrew 2011 combination on one side thereof and a blocker 2010″/break-offhead set screw 2011″ on the other side thereof, the blockers holding apre-tensioned cord 2004 in tension along and with respect to threeclosed bone screws 2012′, none of which are cooperating with a setscrew. Thus, the cord 2004 is in slidable relationship with each of thethree bone screws 2012′. Located adjacent the blocker 2010″ is a bumper2008″ and on-axis spacers 2006′ are located between each of the screws2012′. It is noted that there is no bumper between the blocker 2010 andthe bone screw 2012′. However, in some embodiments, such a bumper may beincluded. The bumper 2008″ overlaps an inner portion of the blocker2010″ as best shown in FIG. 68 . FIG. 66 illustrates the connector 3002′prior to tensioning the cord 2004. FIGS. 67 and 68 illustrate theconnector 3002′ in a tensioned state with the bumper 2008″ incompression and the blocker break-off head already removed, exposing aninner drive of the set screw 2011″ if loosening and removal orrepositioning and further tightening of the cord 2004 is required.

It is to be understood that while certain forms of the present inventionhave been illustrated and described herein, it is not to be limited tothe specific forms or arrangement of parts described and shown.

What is claimed and desired to be secured by Letters Patent is asfollows:
 1. A longitudinal connecting member assembly configured tosupport a portion of a spine of a patient, the assembly comprising: afirst and a second bone anchor, each configured to be locked by aclosure; a tensionable cord extending between the first and second boneanchors and being in slidable relation with respect to the second boneanchor when the first and second bone anchors are locked by therespective closures; an end structure configured to be releasablysecured to the tensionable cord at least while a portion of thetensionable cord is under tension, the portion of the tensionable cordbeing located between the first bone anchor and the end structure andbetween the second bone anchor and the end structure, the end structurehaving a non-threaded through-bore configured to receive the tensionablecord along a longitudinal axis extending through the end structure andhaving a cylindrical outer surface coaxial with the longitudinal axisand a planar outer end surface orthogonal to the cylindrical outersurface; and a spacer slidably positioned on the tensionable cordbetween the end structure and the second bone anchor, the spacerconfigured to be compressed and space the planar outer end surface fromthe second bone anchor when the tensionable cord is tensioned andsecured to the end structure, wherein the tensionable cord isretensionable after the end structure has been secured to thetensionable cord and the first and second bone anchors have been locked,wherein the end structure includes a planar inner end surface orthogonalto the cylindrical outer surface and is configured to directly engagethe spacer, and wherein the planar inner end surface is spaced inwardlyapart from the planar outer end surface.
 2. The assembly of claim 1,wherein the end structure is positioned entirely outside of the firstand second bone anchors.
 3. The assembly of claim 1, wherein the endstructure has a portion configured to be moved toward the tensionablecord, thereby fixing the tensionable cord within the through-bore. 4.The assembly of claim 1, further comprising a second spacer locatedbetween the first and second bone anchors, the second spacer having athrough-bore that slidingly receives the tensionable cord.
 5. Theassembly of claim 4, wherein the second spacer is compressible.
 6. Theassembly of claim 1, wherein at least one of the first and second boneanchors is a polyaxial screw, the polyaxial screw having a shank and areceiver for holding the tensionable cord, the receiver being pivotablewith respect to the shank, and the closure is configured to capture thetensionable cord within the receiver.
 7. The assembly of claim 1,wherein the end structure includes an elongate opening on thecylindrical outer surface, the elongate opening having planar sidesurfaces parallel to the planar outer end surface.
 8. The assembly ofclaim 1, wherein the end structure is configured to secure thetensionable cord with at least one indentation within the through-bore.9. The assembly of claim 1, wherein the end structure is configured tosecure the tensionable cord by deforming the tensionable cord against aninner surface of the through-bore.
 10. The assembly of claim 1, whereinthe end structure is configured to secure the tensionable cord withoutpenetrating the tensionable cord.
 11. An end blocker subassemblyconfigured to be used with a longitudinal connecting member assembly,the assembly including first and second bone anchors supporting aportion of a spine of a patient, each bone anchor including a receiverconfigured to hold a tensionable cord and a closure configured tocapture the tensionable cord in the receiver, the tensionable cordextending between the first and second bone anchors and being inslidable relation with respect to the second bone anchor when the firstand second bone anchors are locked by the respective closures, the endblocker subassembly comprising: a rigid end structure configured to bereleasably secured to the tensionable cord at least while a portion ofthe tensionable cord is under tension, the portion of the tensionablecord being located between the first bone anchor and the rigid endstructure and between the second bone anchor and the rigid endstructure, the rigid end structure having a non-threaded through-boreconfigured to receive the tensionable cord along a longitudinal axisextending through the rigid end structure and having a cylindrical outersurface coaxial with the longitudinal axis and a planar outer endsurface orthogonal to the cylindrical outer surface; and a compressiblespacer slidably positioned on the tensionable cord between the rigid endstructure and the second bone anchor, the compressible spacer configuredto be compressed and separate the planar outer end surface from thesecond bone anchor when the tensionable cord is tensioned and secured tothe rigid end structure, wherein the tensionable cord is retensionablewith a cord pulling tool after the end structure has been secured to thetensionable cord and the first and second bone anchors are in a lockedposition by their respective closures, wherein the rigid end structureincludes a planar inner end surface orthogonal to the cylindrical outersurface and is configured to directly engage the compressible spacer,and wherein the planar inner end surface is spaced inwardly apart fromthe planar outer end surface.
 12. The subassembly of claim 11, whereinthe rigid end structure is positioned entirely outside of the first andsecond bone anchors.
 13. The subassembly of claim 11, wherein the rigidend structure has at least one portion that is configured to be movedtoward the tensionable cord, thereby fixing the tensionable cord withinthe through-bore.
 14. The subassembly of claim 11, further comprising asecond spacer located between the first and second bone anchors, thesecond spacer having a through-bore that slidingly receives thetensionable cord.
 15. The subassembly of claim 14, wherein the secondspacer is compressible.
 16. The subassembly of claim 11, wherein atleast one of the first and second bone anchors is a polyaxial screw. 17.The subassembly of claim 11, wherein the rigid end structure includes anelongate opening on the cylindrical outer surface, the elongate openinghaving planar side surfaces parallel to the planar outer end surface.18. The subassembly of claim 11, wherein the rigid end structure isconfigured to secure the tensionable cord with at least one indentationwithin the through-bore.
 19. The subassembly of claim 11, wherein therigid end structure is configured to secure the tensionable cord bydeforming the tensionable cord against an inner surface of thethrough-bore.
 20. The subassembly of claim 11, wherein the rigid endstructure is configured to secure the tensionable cord withoutpenetrating the tensionable cord.